JP2000113452A - Optical disk, its manufacturing device and method, and reproducing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain an optical disk manufacturing device that prevents a pirated edition from being made regardless of the method either by sending in a reproducing signal directly into a recording device or by making a physical transfer. SOLUTION: This device is designed to manufacture an optical disk in which recorded digital information can be read out by the irradiation of a laser beam. In this case, the device is provided with an encryption means 22, 23 for ciphering inputted digital information based on plural pieces of key information, means 2 for manufacturing an optical disk substrate 4 in which the ciphered digital information and the key information are recorded as change in the physical shape, means 41 for forming a reflection film on the optical disk substrate 4, and a means 7 for recording the key information on the optical disk substrate on which the reflection film is formed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an optical disk manufacturing apparatus, an optical disk manufacturing method, an optical disk, and an optical disk reproducing method.

[0002]

2. Description of the Related Art In a conventional compact disc (CD), an IFPI (International Federation System) is provided in a portion inside an area where an audio signal and a signal used by a user such as a TOC (Table of Contents) are recorded.
f the Phonographic Industry) code was recorded. In this code, a code indicating a maker, a manufacturing site, a disk number and the like is stamped in the above-mentioned area for the purpose of preventing piracy.

[0003]

According to this method, codes indicating a maker, a factory, a disk number, and the like recorded on a compact disk can be visually recognized. Therefore, a reproducing apparatus for reproducing a compact disk or the like cannot read these codes. For this reason, there is a problem that the contents of these codes cannot be reflected in the operation control of the reproducing apparatus.

As a method of solving such a disadvantage, for example, in Japanese Patent Application No. 9-67843, the width of pits recorded on a disk is changed by changing the output of a recording laser to change the width of pits recorded on the disk. A unique code was recorded.

Therefore, for example, as a first example, a recording signal on a disk is encrypted in advance, and key information for decryption is converted into a pit width using a method described in the above-mentioned patent application. Can be recorded as a change. The playback device is configured to detect the key information recorded in this way and to decrypt the code based on the detected key information. In the case of a pirated disk, it is considered that the key information is not recorded, so the encryption is not released and normal reproduction cannot be performed. Therefore, it is considered that the pirated disk has no value if the reproducing apparatus is configured as described above, and the appearance of the pirated disk can be substantially prevented.

[0006] It is said that there are two methods of creating a pirated copy: a method of directly sending a reproduced signal from a disk to a recording device, and a method of transferring the physical shape of the disk as it is. When a pirated copy is created using the method of directly sending a reproduction signal to a recording device for a disc created by the method described as the first example, information recorded as "pits" of pits is lost. However, the key information recorded as the change in the pit width is not recorded on the pirated disk. Therefore, by adopting the method described as the first example, it is possible to prevent creation of a pirated disk by a method in which a reproduced signal is directly sent to a recording device. However, when a pirated disk is created by a method of physically transferring a disk created by this method, key information recorded as a change in pit width is also copied to the pirated disk. For this reason, the method of the first example has a problem that it is not possible to prevent copying of a pirated disk created by physical transfer.

Therefore, as a means for solving such a problem, a second example is considered. In the second example, key information is recorded as a change in reflectance regardless of the physical shape. In other words, a groove is formed in an area such as a lead-out area of an optical disk, and a reflective film is irradiated with a powerful laser beam to change a reflection characteristic to record information similar to a pit row. It is possible to do.

When the key information is recorded as a change in the reflectance, the key information is recorded as a change in the reflection characteristic of the reflection film. Since the key information is not recorded as a physical shape (pit), the key information is not copied to a pirated disk created by using a pirated generation method by physical transfer. Therefore, it is possible to compensate for the drawback of the first example and prevent creation of a pirated copy by physical transfer.

However, in the second example, when a pirated copy is created by sending a reproduced signal from a disc to a recording device as it is, the key information recorded in the lead-out area is not changed. There is a disadvantage of being copied.

[0010] As described above, the piracy prevention method proposed so far can prevent piracy by only one of the pirated disk creation methods currently considered. Was. However, if a pirated optical disc is created using an unsupported method, it will be totally powerless.

Accordingly, an object of the present invention is to solve the conventional disadvantages of piracy prevention, and to use any of the method of directly sending a reproduced signal to a recording device and the method of performing physical transfer. And a manufacturing method of an optical disk that makes it impossible to create a disk, and an optical disk provided with such anti-piracy measures and a reproduction method for reproducing an optical disk provided with such anti-piracy measures. It is.

[0012]

An optical disk manufacturing apparatus according to a first aspect of the present invention manufactures an optical disk in which recorded digital information is read out by irradiating a laser beam. , An encrypting means for encrypting input digital information based on a plurality of key information, and an optical disk substrate for manufacturing an optical disk substrate on which the encrypted digital information and key information are recorded as a change in physical shape. Means, a reflection film forming means for forming a reflection film on the optical disk substrate, and key information recording means for recording key information on the optical disk substrate on which the reflection film is formed.

According to the first aspect of the present invention, the encrypting means encrypts the input digital information based on the plurality of key information, and the manufacturing means of the optical disc substrate converts the encrypted digital information and the key information into physical information. Manufacturing an optical disk substrate recorded as a change in the general shape, the reflection film forming means forms a reflection film on the optical disk substrate, and the key information recording means forms the key information on the optical disk substrate on which the reflection film is formed. Record

[0014]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A first aspect of the present invention is an optical disk manufacturing apparatus for manufacturing an optical disk in which recorded digital information is read out by irradiating a laser beam. Means for encrypting based on the key information of the optical disk, means for manufacturing an optical disk substrate for recording the encrypted digital information and key information as a change in physical shape, and reflection on the optical disk substrate An optical disk manufacturing apparatus includes: a reflective film forming unit that forms a film; and a key information recording unit that records key information on an optical disk substrate on which the reflective film is formed.

According to a second aspect of the present invention, in the optical disk manufacturing apparatus according to the first aspect, the optical disk substrate manufacturing means includes:
Exposure means for exposing the optical disk master by focusing the laser beam on the optical disk master according to the encrypted digital information and key information, and the physical shape by subjecting the exposed optical disk master to chemical processing An optical disc manufacturing apparatus includes a stamper forming means for forming a changed stamper, and a duplicating means for transferring a physical shape change on the stamper to generate a plurality of optical disc substrates.

According to a third aspect of the present invention, in the optical disk manufacturing apparatus according to the second aspect of the present invention, the exposing means comprises: a laser light intensity modulating means for modulating the intensity of the laser beam in accordance with the encrypted digital information; An optical disc manufacturing apparatus comprising: a laser beam condensing position changing means for changing a laser beam condensing position based on the laser beam.

According to a fourth aspect of the present invention, in the optical disk manufacturing apparatus according to the third aspect of the present invention, the laser beam intensity modulating means includes a modulating means for generating a modulation signal in accordance with the encrypted digital information, and a laser beam in accordance with the modulation signal. And a light modulating means for turning on / off the optical disk.

According to a fifth aspect of the present invention, in the optical disk manufacturing apparatus according to the first aspect of the present invention, the key information recording means includes a laser beam generating means for generating a laser beam, and a light intensity modulation for modulating the laser beam according to the key information. An optical disc manufacturing apparatus comprising: means for condensing a modulated laser beam at a predetermined position on an optical disc for irradiation.

According to a sixth aspect of the present invention, there is provided an optical disk manufacturing method for manufacturing an optical disk in which recorded digital information is read out by irradiating a laser beam, wherein the input digital information is stored in a plurality of keys. An encryption step for encrypting based on the information; an optical disk substrate manufacturing step for manufacturing an optical disk substrate on which the encrypted digital information and key information are recorded as a change in physical shape; and a reflective film on the optical disk substrate. A method for manufacturing an optical disk, comprising: a reflective film forming step of forming; and a key information recording step of recording key information on an optical disk substrate on which the reflective film is formed.

According to a seventh aspect of the present invention, in the optical disk manufacturing method according to the sixth aspect of the present invention, the optical disk substrate generating step includes focusing the laser beam on the optical disk master according to the encrypted digital information and key information. An exposure step of exposing the optical disk master, a stamper forming step of forming a stamper having a physical shape change by applying a chemical treatment to the exposed optical disk master, and transferring the physical shape change on the stamper And
And a duplication step of generating a plurality of optical disk substrates.

According to an eighth aspect of the present invention, in the optical disk manufacturing method of the sixth aspect, the key information recording step includes a laser beam generation step of generating a laser beam and a modulation step of modulating the laser beam according to the key information. And a laser irradiation step of converging and irradiating a laser beam on the optical disk substrate.

According to a ninth aspect of the present invention, there is provided an optical disk in which digital information is recorded as a change in physical shape and the digital information is reproduced by reflecting an incident laser beam by a reflection film. The digital information is encrypted with a plurality of key information, one of the plurality of key information is recorded as a change in physical shape on an optical disc, and at least one of the plurality of key information is stored. Is an optical disk recorded as a change in reflectance of a reflective film on the optical disk.

According to a tenth aspect of the present invention, there is provided an optical disk reproducing method for reproducing an optical disk on which encrypted digital information is recorded, wherein the first key information recorded as a change in physical shape on the optical disk is stored in the optical disk. A first reproducing step of reproducing, a second reproducing step of reproducing second key information recorded as a change in reflectance on the optical disk, and a reproducing of digital information recorded on the optical disk; A decryption step of decrypting the reproduced digital information using the second key information.

[0024]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an optical disk manufacturing apparatus, an optical disk manufacturing method, and an optical disk according to specific embodiments of the present invention will be described in detail with reference to the drawings. First, a manufacturing apparatus and a manufacturing method of an optical disc according to a specific example will be described with reference to FIG. The optical disk manufacturing apparatus of this specific example is a compact disk (CD)
This is the case of the manufacturing apparatus. In FIG. 1, a digital audio signal SA reproduced from a magnetic tape by a digital tape recorder 21 is transmitted to a first encryption circuit 22.
And is encrypted using the first key information signal KY1 from the first key information generation circuit 24. The encrypted digital audio signal S from the first encryption circuit 22
B is supplied to the second encryption circuit 23 and is encrypted using the second key information signal KY2 from the second key information generation circuit 25. The double encrypted digital audio signal SC obtained from the second encryption circuit 23 and the second key information signal KY2 from the second key information generation circuit 25 are supplied to the disk substrate manufacturing apparatus 2. The disk substrate 4 on which the double encrypted digital audio signal SC and the second key information signal KY2 are recorded as uneven pits is created.

In the cutting machine 3 of the disc substrate manufacturing apparatus 2, the double encrypted audio signal SC from the second encryption circuit 23 and the second key information signal from the second key information generation circuit 23 are KY2 And the laser beam is modulated, and the master disk 26 is exposed by the modulated laser beam.

The exposed master disk 26 is subjected to a developing process and a plating process by a developing / plating device 27, whereby a stamper 28 is obtained. Further, the stamper 28 is loaded into an injection molding machine 29, and the injection molding machine 29 creates the disk substrate 4 formed of a plastic material such as polycarbonate.
The double encrypted digital audio signal SC and the key information signal KY2 are recorded on the disk substrate 4 created in this manner as minute irregularities (pits).

Next, a reflection film is formed on the disk substrate 4 by the reflection film forming apparatus 41, and the semi-finished disk 5 is obtained. On this semi-finished disk 5, the double encrypted digital audio signal SC and the second key information signal KY2 from the second key information generating circuit 25 are recorded as uneven pits, and a laser beam is applied to the opposite side of the pits. A reflecting film that reflects light is formed. However, the first key information signal KY1 generated by the first key information generation circuit 24 is not recorded on the semi-finished disk 5. Therefore, even if the semi-finished disk 5 is inserted into the optical disk player, the encryption by the first encryption circuit 22 cannot be decrypted as it is, and it is impossible to reproduce music.

Finally, the semi-finished disc 5 is inserted into the CD-R recording device 7. In the CD-R recording device 7, the first key information signal KY1 from the first key information generating circuit 24 is supplied to the computer 6, and in response to an instruction from the computer 6, an area where user data is not recorded is recorded. (Lead-out area) is accessed, and the first key information signal KY1 from the first key information generation circuit 24 is additionally recorded. Here, the information signal additionally recorded by the CD-R recording device 7 is recorded as a change in the reflectance of the reflection film formed by the reflection film forming device 41.

The compact disk (completed disk) 8 completed as described above is a reproduced digital audio signal SA obtained from the digital tape recorder 21.
In addition, the second key information signal KY2 from the second key information generation circuit 25 and the first key information KY1 from the first key information generation circuit 24 are recorded. Therefore, in the case of reproducing music or the like of the compact disk 8, the optical disk reproducing device described later can obtain the information of the first key information signal KY 1 and the second key information signal KY 2 from the compact disk 8. Since the double encryption can be released, music can be enjoyed in the same manner as a conventional compact disc.

The first encryption circuit 22 uses the first key information signal KY1 generated by the first key information generation circuit 24 to encrypt the digital audio signal SA with the DES code, and performs encryption. And outputs the converted digital audio signal SB. The DES code is (Data Enc
(ryption Standard), a widely used encryption method. Similarly, the second encryption circuit 23 uses the second key information signal KY2 generated by the second key information generation circuit 25 to encrypt the encrypted digital audio signal SB with the DES code, and performs double encryption. And outputs the converted digital audio signal SC.

The first key information generating circuit 24 and the second key information generating circuit 25 output a different first key information signal KY1 and a different second key information signal KY2 each time a new disc is cut. . Such a key information signal generating circuit is, for example, an LFSR (Linear Feedback Shift R
egister).

Next, the configuration of the cutting machine 3 in FIG. 1 will be described with reference to FIG. The cutting machine 3 is an apparatus for exposing the double encrypted digital audio signal SC and the second key information signal KY2 to the master disk 26 as described above. The modulation circuit 31 performs data processing specified for the compact disc on the double encrypted digital audio signal SC,
An EFM signal SD is created and sent to the optical modulator 35. That is, an error correction code is added to the digital audio signal SC that has been double-encrypted, then interleave processing is performed, and further EFM modulation is performed to obtain an EFM signal SD.
Is generated. Further, the modulation circuit 31 is provided with a TOC (Table Of Con-
tents) and the subcode data including the information
D is inserted into the subcode region.

The modulation circuit 32 has a second key information signal KY2
To the key information modulation signal KY having an analog waveform.
D is sent to the optical modulator 34. Such FM modulation has the same principle as that used for recording address information of, for example, an MD (mini-disc) on an optical disc, and a detailed description thereof will be omitted. In the FM modulation, for example, a clock signal or the like is embedded so that the key information KY2 can be restored from the key information modulation signal KYD.

The modulation circuit 32 is set by a system controller (not shown) so as to operate only during the period when the cutting machine 3 is recording in the lead-in area. Therefore, when the cutting machine 3 is cutting the data area and the lead-out area, the key information modulation signal KYD has a constant voltage,
The modulation of the signal by the optical modulator 34 is not performed.

The disk master 26 is a spindle motor 38
Is driven to rotate. The spindle motor 38 is controlled by a spindle servo circuit 39. Actually, an FG signal generator (not shown) provided at the bottom of the spindle motor 38 outputs an FG signal whose signal level rises at every predetermined rotation angle. The spindle servo circuit 39 drives the spindle motor 38 so that the frequency of the FG signal becomes a predetermined frequency. In this way, the master disc 26 is driven to rotate at a predetermined rotation speed.

The recording laser light source 33 has a laser beam L
1 is emitted to the optical modulator 34 and the optical modulator 35.
The recording laser light source 33 is composed of, for example, a gas laser or the like. The light modulator 34 and the light modulator 35 are configured by an electroacoustic optical element or the like. Optical modulator 3
Reference numeral 4 changes the traveling direction of the laser beam L1 incident from the recording laser light source 33 according to the key information modulation signal KYD supplied from the modulation circuit 32. That is, the optical modulator 3
4 outputs a laser beam L2 whose angle in the traveling direction slightly changes according to the level of the key information modulation signal KYD. Such modulation of the traveling angle of a laser beam is generally used as an AOD (Acoustic Optical Deflector).

The laser beam L2 whose traveling direction has been changed by the key information modulation signal KYD in this manner enters the optical modulator 35 and is supplied from the modulation circuit 31 to the EF.
On / off control is performed by the optical modulator 35 in accordance with an M (Eight to Fourteen Modulation) signal SD, and the laser light is emitted as a laser beam L3.

The mirror 36 bends the optical path of the laser beam L 3, for example, by 90 ° and emits it toward the master disk 26. The objective lens 37 focuses the light reflected by the mirror 36 on the recording surface of the master disc 26. By being reflected by the mirror 36, the laser beam L3
Changes in the traveling direction of the (by the key information modulation signal KYD)
It is recorded on the disk as the positional deviation of the focused spot.

The mirror 36 and the objective lens 37
Is a disk master 26 by a thread mechanism (not shown).
Are sequentially moved in the radial direction in synchronization with the rotation of. In this way, by sequentially shifting the focus position of the laser beam L3 from, for example, the inner circumference to the outer circumference of the disk master 2, tracks can be formed in a spiral shape on the disk master 26. Then, pits are sequentially formed on this track according to the EFM signal SD. Further, as described above, since the traveling directions of the laser beams L2 and L3 are modulated by the optical modulator 34, the center position of the pit row formed in the lead-in area is set with respect to the track in accordance with the key information modulation signal KYD. The horizontal shift is given.

Double encrypted digital audio signal SC
The master disk 26 is exposed by the laser beam L3 modulated by the second key information signal KY2.

The exposed master disk 26 is subjected to development and plating as described with reference to FIG.
A stamper 28 is created. Furthermore, this stamper 2
8 is loaded into an injection molding machine 29, and the injection molding machine 29 creates a disk substrate 4 made of a plastic material such as polycarbonate. The reflection film is formed on the disk substrate 4 by the reflection film forming device 41, and the semi-finished disk 5 is obtained. Finally, the semi-finished disc 5 is a CD
-R is inserted into the recording device 7. In response to an instruction from the computer 6, the CD-R recording device 7 accesses an area (lead-out area) where no user data is recorded, and outputs the first key information from the first key information generation circuit 24. The signal KY1 is additionally recorded. Here, the information additionally recorded by the CD-R recording device 7 is recorded as a change in the reflectance of the reflection film formed by the reflection film forming machine 41.

The basic structure of the CD-R recording apparatus 7 is the same as that of a commercially available CD-R recording apparatus except that the CD-R recording apparatus 7 is modified so as to access the lead-out area.

FIG. 3A schematically shows a compact disk (completed disk) 8 completed as described above.
As shown in FIG. 3A, the compact disc 8 is divided into three areas. That is, the innermost side is a lead-in area (lead-in) LI, the middle part is a data area DA, and the outermost part is a lead-out area (lead-out) LO.

In the lead-in area LI, TOC information for accessing the compact disc 8 and a second key information signal KY2 are recorded. Therefore, when the state of the lead-in area is observed with a microscope or the like, for example, FIG.
As shown in FIG. 7, it can be observed that the TOC information is recorded as pits. The center position of the pit is slightly shifted from the center of the track, and the second key information signal KY2 is recorded due to this shift.

The data area DA is an area where the double encrypted digital audio signal SC is recorded. When this portion is observed with a microscope or the like, it can be seen that, for example, as shown in FIG. 3C, the double encrypted digital audio signal SC information is recorded as pits. Since the recording of the second key information signal KY2 is not performed in the data area DA, the center position of the pit does not change.

The key information KY1 is recorded in the lead-out area LO by the CD-R recording device 7. Therefore, when this part is observed with a microscope or the like, for example, as shown in FIG. 3D, the first key information signal KY1 is recorded as a change in reflectance. It can be seen that information is not recorded using physical changes (such as unevenness).

For example, consider a case in which a pirated creator obtains the compact disk 8 created in this way, and sends a reproduced signal obtained from the compact disk 8 to the cutting machine again to create a pirated copy. As a result, TOC information, data area information, and lead-out information recorded in the lead-in LI are all sent to the cutting machine,
It is also recorded on pirated disks. However, lead-in L
The second key information signal KY2 recorded in I as a pit position shift does not appear in the reproduced signal, so that it is not recorded on the pirated disk. Therefore, in the pirated disk created in this manner, the encryption by the second key information signal KY2 cannot be decrypted, and thus it becomes impossible to reproduce a music signal or the like. Therefore, the value of the pirated disk is lost, and it is possible to prevent creation of a pirated disk using such a method.

Next, let us consider a case where a pirated trader creates a pirated copy by obtaining the compact disc 8 and physically transferring pits. In such a case, the second position recorded as a pit displacement in the lead-in is used.
It is considered that the key information signal KY2 is also transferred as it is to the pirated disk. However, readout LO
The first key information signal KY1 recorded in is recorded due to a change in reflectance, and does not have any physical unevenness.
Therefore, the first key information signal KY1 is not transferred to a pirated disk. As a result, the created pirated disk cannot be decrypted because the encryption by the first key information signal KY1 cannot be decrypted and cannot be reproduced. Therefore, the value of the pirated disk is lost, and the creation of the pirated disk using such a method can be prevented.

As described above, according to the specific example of the embodiment of the present invention, it is possible to prevent creation of a pirated copy by both a method of physically transferring and a method of directly sending a reproduced signal to a cutting machine. Become.

Next, with reference to FIG. 4, a reproducing apparatus 50 for reproducing the compact disk 8 created as described above will be described.

The reproducing apparatus 50 shown in FIG. 4 is controlled by a system controller 64. The compact disk 8 is rotated by a spindle motor 51. Spindle motor 51 and optical pickup 53
Are controlled by the servo circuit 52 to perform a predetermined operation. The reproduced RF signal generated by the optical pickup 53 is supplied to a binarization circuit 54. Optical pickup 5
3 is supplied to the A / D converter 61
Supplied to

The binarization circuit 54 performs binarization by comparing the supplied reproduced RF signal with a predetermined slice level to generate a binarized signal. This binarized signal is E
The signal is supplied to the FM demodulation circuit 55. EFM demodulation circuit 55
Performs EFM demodulation from the binary signal to generate an 8-bit unit signal, and supplies the generated 8-bit unit signal to an error correction circuit (ECC) circuit 56.

The ECC circuit 56 corrects an error in the output of the EFM demodulation circuit 55 based on the ECC (Error Correcting Code) added in the encoding at the time of recording.
Such an error is caused, for example, by a defect on the compact disc 8 or the like.

On the other hand, the A / D converter 61 digitizes (quantizes) the push-pull signal PP and supplies it to the DSP 62 as a digital reproduction signal DRF. Since the push-pull signal PP is a signal proportional to the displacement of the pit from the track center, the second key information signal KY
2 contains the information recorded. DSP62
Is a digital signal processor, which reproduces a digital reproduced signal DRF according to a program recorded therein.
And performs signal processing on F.
The second key information signal KY2 is obtained by demodulating the M modulation.

Using the second key information signal KY2 obtained as described above, the first encryption processing circuit 57 cancels the encryption processing applied to the output signal from the ECC circuit 156. The information that has been decrypted by the first encryption processing circuit 57 (the second encryption circuit 23 in FIG. 1) is subsequently supplied to the second encryption processing circuit 58.
At the same time, the signal from the ECC circuit 156 is also supplied to the memory 63. When the first key information signal KY1 is included in the output from the second encryption processing circuit 57, the system controller 64 stores the first key information signal KY1 in the memory 63.
The memory 63 is instructed to store it in the memory 63. As a result, the first key information signal KY1 stored in the memory 63 is always supplied to the second encryption processing circuit 58,
Can decrypt the first encryption (by the first encryption circuit 22 in FIG. 1).

As described above, the digital audio signal SA is restored at the output side of the second encryption processing circuit 58 by performing the decryption processing. The digital audio signal SA thus obtained is
The signal is converted into an analog audio signal by the D / A converter 59, output to the output terminal 60, supplied to a speaker or the like, and emitted.

Incidentally, the operation of decryption as described above is performed by the system controller 64. The system controller 64 controls the new optical disk 8
Each time is inserted, the playback device 150 performs a predetermined operation as shown in the flowchart of FIG.
It is configured to reliably realize the above-described decryption processing.

In the processing of the system controller 64 shown in FIG. 5, first, in step ST-1, the system controller 64 gives an instruction to each part of the system including the servo circuit 52 to transfer the optical pickup 53 to the lead-in area LI of the optical disk 8. An instruction is issued to move the focal position of the emitted light beam. Next, as step ST-2,
Push-pull signal P supplied from optical pickup 53
P is quantized by the A / D converter 61 and processed by the DSP 62, thereby decoding the information recorded as the second key information signal KY2. Next, step ST-
As 3, the decrypted second key information signal KY2 is output to the output terminal of the DSP 62, and the value is held.

Subsequently, in step ST-4, the system controller 64 issues an instruction to move the focal position of the light beam emitted from the optical pickup 53 to the lead-out area LO. Next, in step ST-5, the read first key information signal KY1 is stored in the memory 63.
To keep it. As described above, since both the first key information KY1 and the second key information KY2 have been obtained, in step ST-6, the system controller 64 reproduces the compact disc 8 and
Control the whole to emit sound.

As described above, the system controller 6
4 controls the whole, so that the lead-in area LI
Then, the key information recorded in the lead-out area LO is read out, and the sound is emitted after the correct decryption is performed. As a result, it is possible to prevent a situation in which a large noise is emitted from a speaker or the like without performing the decryption.

When the compact disk 8 is a legitimate (non-pirated) disk, both the first and second key information signals KY1 and KY2 are correctly decrypted. As a result, the first and second encryption processing circuits 57 and 58 can obtain information necessary for decryption. Therefore, by sending the output of the second encryption processing circuit 58 to the D / A converter 59, the output of the D / A converter 59 becomes, for example, a music signal, and the music recorded on the compact disc 8 is converted to the music signal. You can enjoy it.

For example, in the case of a pirated disk produced by reproducing the disk obtained by the optical disk manufacturing apparatus of the present invention once and sending the obtained reproduced signal to the cutting machine again, the pit is recorded as a pit position displacement. The second key information signal KY2 is missing. Therefore, even if the pirated disk is reproduced by the optical disk reproducing apparatus as shown in FIG. 4, the user cannot enjoy music from such a pirated disk. Further, as described above, even when a pirated copy is created by a method in which the physical shape of a disc is transferred, the user cannot enjoy music.

As described above, according to the optical disk reproducing apparatus of this specific example, the value of the pirated disk can be significantly reduced regardless of which method is used. It is possible to prevent the spread.

In the specific example of the above-described embodiment, the case where the second key information signal KY2 is recorded as the pit position displacement has been described. However, the present invention is not limited to this.
For example, as a subtle change in the pit width, the second key information signal K
It is also possible to record Y2. In this case, the optical disc reproducing apparatus does not need the optical system for detecting the push-pull signal, and the effect of simplifying the structure of the optical disc reproducing apparatus and reducing the cost is expected.

[0065]

According to the first to fifth aspects of the present invention, there is provided an optical disk manufacturing apparatus for manufacturing an optical disk capable of reading recorded digital information by irradiating a laser beam. Encryption means for encrypting information based on a plurality of key information, means for manufacturing an optical disk substrate for manufacturing an optical disk substrate on which the encrypted digital information and key information are recorded as a change in physical shape, and an optical disk substrate An optical disk manufacturing apparatus having the following effects because it has a reflective film forming means for forming a reflective film thereon and a key information recording means for recording key information on an optical disk substrate having the reflective film formed thereon Can be obtained. That is, according to the first to fifth aspects of the present invention, the key information is recorded by two different methods, ie, a physical shape change and a reflectance change of the reflection film. The manufactured optical disk cannot create a pirated disk even by physical transfer, nor can the reproduced signal reproduced from the optical disk manufactured by the manufacturing apparatus of the present invention be directly sent to a cutting machine or the like. You cannot make pirated discs. Therefore, according to the optical disk manufacturing apparatuses of the first to fifth aspects of the present invention, it is possible to manufacture an optical disk capable of protecting the interests of a valid copyright holder.

According to the sixth to eighth aspects of the present invention, in an optical disk manufacturing method for manufacturing an optical disk in which recorded digital information is read out by irradiating a laser beam, An encryption step of encrypting information based on a plurality of key information; an optical disk substrate manufacturing step of manufacturing an optical disk substrate on which the encrypted digital information and key information are recorded as a change in physical shape; Since the method includes a reflective film forming step of forming a reflective film thereon and a key information recording step of recording key information on an optical disk substrate on which the reflective film is formed, a method of manufacturing an optical disk having the following effects can be obtained. Can be obtained. That is,
According to the sixth to eighth aspects of the present invention, the optical disc manufactured by the optical disc manufacturing method of the present invention cannot produce a pirated disc even by physical transfer,
Further, a pirated disk cannot be produced by a method of directly sending a reproduction signal reproduced from an optical disk manufactured by the optical disk manufacturing method of the present invention to a cutting machine or the like. Therefore, according to the sixth to eighth optical disk manufacturing methods of the present invention, it is possible to manufacture an optical disk capable of protecting the interests of a valid copyright holder.

According to the ninth aspect of the present invention, an optical disk in which digital information is recorded as a change in physical shape and the digital information is reproduced by reflecting an incident laser beam by a reflection film. At
The digital information is encrypted with a plurality of key information, one of the plurality of key information is recorded as a change in physical shape on an optical disc, and at least one of the plurality of key information is stored. Is recorded as a change in the reflectivity of the reflective film on the optical disk, so that an optical disk having the following effects can be obtained. That is,
According to the ninth aspect of the present invention, the digital information recorded on the optical disk is encrypted with a plurality of key information, and one of the plurality of key information is recorded on the optical disk as a change in physical shape, In addition, since at least one of the plurality of key information is recorded as a change in the reflectance of the reflection film on the optical disk, a pirated disk cannot be created by physical transfer. A pirated disk cannot be created by a method of directly sending a reproduced signal reproduced from an optical disk to a cutting machine or the like. Therefore, according to the optical disk of the present invention, it is possible to protect the interests of a valid copyright holder.

According to the tenth aspect of the present invention, there is provided an optical disc in which digital information is recorded as a change in physical shape and the digital information is read out by reflecting an incident laser beam by a reflection film. The digital information is encrypted with a plurality of key information, and one of the plurality of key information is recorded on an optical disk as a change in physical shape, and at least one of the plurality of key information is recorded. First, since the change is recorded as a change in the reflectivity of the reflection film on the optical disk, it is possible to obtain an optical disk reproducing method having the following effects. That is, according to the tenth aspect of the present invention, it is possible to obtain a method of reproducing an optical disk capable of correctly decrypting the encrypted information and reproducing the recorded information even if the disk is pirated by encryption. it can.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a specific example of an optical disk manufacturing apparatus according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration of a cutting machine of the optical disk manufacturing apparatus of FIG.

FIG. 3 is a diagram showing an optical disc of a specific example of an embodiment of the present invention, wherein A is a perspective view of the optical disc, B is a diagram showing a lead-in area, C is a diagram showing a data area, and D is a lead. It is a diagram showing an out area.

FIG. 4 is a block diagram showing an optical disk reproducing apparatus according to a specific example of the embodiment of the present invention.

FIG. 5 is a flowchart showing an operation of a system controller of the optical disk reproducing apparatus of FIG. 4;

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Optical disk manufacturing apparatus, 2 ... Disk substrate manufacturing apparatus, 4 ... Disk substrate, 5 ... Semi-finished disk, 6 ... Computer, 7 ... CD-R recording apparatus, 8 ... Compact disk, 8 ... Completed disk, 21 ... Digital tape recorder, 22, 23: encryption circuit, 24, 25: key information generation circuit, 50: optical disk reproducing device, 51: spindle motor, 52: servo circuit, 53: optical pickup,
54 binarization circuit, 55 EFM demodulation circuit, 56 error correction circuit, 57, 58 encryption processing circuit, 59 D / A converter, 61 A / D converter, 62 DSP, 63 memory , 64 ... System controller

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Claims (10)

[Claims] 1. An optical disk manufacturing apparatus for manufacturing an optical disk capable of reading recorded digital information by irradiating a laser beam, wherein the input digital information is encrypted based on a plurality of key information. Encrypting means; optical disk substrate manufacturing means for manufacturing an optical disk substrate on which the encrypted digital information and the key information are recorded as a change in physical shape; and a reflective film for forming a reflective film on the optical disk substrate An apparatus for manufacturing an optical disk, comprising: forming means; and key information recording means for recording the key information on an optical disk substrate on which the reflective film is formed. 2. The optical disk manufacturing apparatus according to claim 1, wherein the optical disk substrate manufacturing unit focuses a laser beam on an optical disk master according to the encrypted digital information and the key information. Exposure means for exposing the optical disc master, stamper forming means for forming a stamper whose physical shape has been changed by performing a chemical treatment on the exposed optical disc master, and a physical shape on the stamper An optical disk manufacturing apparatus, comprising: a duplication unit that transfers a change to generate a plurality of optical disk substrates. 3. The optical disk manufacturing apparatus according to claim 2, wherein the exposure unit modulates an intensity of the laser beam according to the encrypted digital information, and a key based on the key information. An optical disk manufacturing apparatus, comprising: a laser beam condensing position changing means for changing a condensing position of the laser beam. 4. The optical disk manufacturing apparatus according to claim 3, wherein the laser light intensity modulating means generates a modulation signal according to the encrypted digital information, and modulates the laser beam according to the modulation signal. An optical disk manufacturing apparatus, comprising: an optical modulator for turning on and off. 5. The optical disk manufacturing apparatus according to claim 1, wherein the key information recording unit includes: a laser beam generation unit that generates a laser beam; and a light intensity modulation unit that modulates the laser beam according to the key information. An optical disc manufacturing apparatus comprising: a condensing unit that condenses the modulated laser beam to a predetermined position on the optical disc and irradiates the modulated laser beam with the laser beam. 6. An optical disk manufacturing method for manufacturing an optical disk in which recorded digital information is read out by irradiating a laser beam, wherein the input digital information is encrypted based on a plurality of key information. An optical disk substrate manufacturing step of manufacturing an optical disk substrate on which the encrypted digital information and the key information are recorded as a change in physical shape; and forming a reflective film on the optical disk substrate. A method for manufacturing an optical disk, comprising: a reflection film forming step; and a key information recording step of recording the key information on an optical disk substrate on which the reflection film is formed. 7. The method for manufacturing an optical disk according to claim 6, wherein the optical disk substrate generating step comprises: condensing a laser beam on a master optical disk according to the encrypted digital information and the key information. An exposure step of exposing the master, a stamper forming step of forming a stamper subjected to a physical shape change by performing a chemical treatment on the exposed optical disc master, and a physical shape change on the stamper. A copying step of transferring and generating a plurality of optical disk substrates. 8. The method for manufacturing an optical disk according to claim 6, wherein the key information recording step includes: a laser beam generation step of generating a laser beam; a modulation step of modulating the laser beam according to the key information; A laser irradiation step of condensing and irradiating the laser beam onto the optical disk substrate. 9. An optical disc on which digital information is recorded as a change in physical shape and which reproduces the digital information by reflecting an incident laser beam by a reflection film, wherein the digital information is Encrypted with a plurality of key information, one of the plurality of key information is recorded as a change in physical shape on the optical disc, and at least one of the plurality of key information is Is recorded as a change in reflectivity of a reflection film on the optical disk. 10. An optical disk reproducing method for reproducing an optical disk on which encrypted digital information is recorded, wherein a first key information recorded as a change in physical shape on the optical disk is reproduced. A second reproducing step of reproducing second key information recorded as a change in reflectance on the optical disc; and reproducing the digital information recorded on the optical disc, A decryption step of decrypting the reproduced digital information using the key information of (2).