KR20070117771A - Recording medium and method and apparatus for reproducing data - Google Patents

Abstract

A recording medium, and an apparatus and a method for reproducing data of the recording medium are provided to record copy protection information by pits and spaces. A recording medium comprises a recording layer(35), reflection layers(39), and a dichroic mirror layer(37). Data is recorded in the recording layer by the interference between signal and reference beams. The reflection layers are formed with lands and grooves where copy protection information is recorded by pits and spaces. Decoding keys are recorded in the reflection layers. The dichroic mirror layer is placed between the recording layer and the reflection layer to pass the beam selectively according to the wavelength. The copy protection information is recorded in at least one of a wobble pit shape, a serial pit shape, and a mixed shape of the wobble and serial pit shapes.

Description

Recording medium and method and apparatus for reproducing data

1 and 2 illustrate the structure of a recording medium according to an embodiment of the present invention.

3 is a view for explaining a configuration of a data recording and reproducing apparatus capable of storing data on a recording medium or reproducing recorded data according to an embodiment of the present invention.

FIG. 4 is a diagram illustrating processing of encrypted data as unencrypted data and reproducing in a data reproducing apparatus according to an embodiment of the present invention. FIG.

The present invention relates to a recording medium and an apparatus and method for reproducing data stored on the recording medium.

Representative examples of recording media on which data is recorded include CD (Compact Disc) and DVD (Digital Versatile Disc). CDs and DVDs are recording media that store data using spots of beams emitted from a laser light source.

Although CDs and DVDs use a method of increasing storage capacity by adjusting pitch intervals or increasing recording layers, it is no longer possible to increase storage capacity due to physical limitations.

Meanwhile, with the development of multimedia technology, there is a demand for a recording medium capable of storing more data, a data recording device capable of storing data on such a recording medium, and a data reproducing apparatus capable of reproducing the recording medium.

Accordingly, in recent years, studies on holographic data recording and reproducing apparatus using light interference and diffraction have been actively conducted.

The holographic data recording and reproducing apparatus uses an interference fringe generated by interference of a signal beam and a reference beam.

That is, when a signal beam and a reference beam are irradiated on the recording medium, an interference fringe is formed by the interference between the signal beam and the reference beam, and data is recorded on the recording medium by the interference fringe formed in this way. do.

When the reference beam is irradiated to the recording medium storing the interference fringe, the recorded data is reproduced while diffracting the reference beam from the interference fringe stored in the recording medium.

At this time, the holographic data recorded on the recording medium can be read only by the reference beam used in the recording process, and cannot be read by the reference beam having a different wavelength or phase from the reference beam used at the time of recording. Passed through holographic data.

By using this hologram property, a large number of holographic data can be stored in the same place on the recording medium with different reference beams, thereby making it possible to store a large amount of data inside a small recording medium.

The Angular Multiplexing technique, which is commonly used for this purpose, changes the angle of the reference beam at each recording time to create different reference beams, which allows hundreds to thousands of holographic data to be stored per page. Can be stored in place. In other words, by recording a lot of data in units of pages in the same place, it is possible to record with high storage density.

Here, since the incident angle and the incident position of the reference beam incident on the recording medium should be changed, an actuator for adjusting the incident angle and the incident position of the reference beam is required.

On the other hand, since the holographic data recording and reproducing apparatus records and reproduces in units of pages, a parallel data processing method is used, thereby enabling a high data transfer rate and a large recording density.

On the other hand, the recording medium used in the above-described holographic data recording and reproducing apparatus requires a technology capable of preventing unauthorized copying of contents stored in the recording medium such as a CD or a DVD.

Therefore, a copy protection technology suitable for holographic recording media has been studied.

An object of the present invention is to provide a recording medium capable of copy protection.

It is also an object of the present invention to provide an apparatus and method for reproducing data of a recording medium provided with a copy protection function.

The recording medium according to the present invention includes a recording layer in which data is recorded by interference of a signal beam and a reference beam, a reflection layer in which lands and grooves are formed, and a decryption key is recorded, and positioned between the recording layer and the reflection layer and depending on the wavelength. Optionally, it comprises a dichroic mirror layer for allowing the beam to pass through.

A data reproducing method according to the present invention comprises the steps of obtaining a decryption key from a recording medium by a first beam, acquiring data from the recording medium by a second beam, and decrypting the data using the decryption key. And reproducing the decoded data.

In accordance with another aspect of the present invention, a data reproducing apparatus includes: a decryption key extractor extracting a decryption key by a first beam incident from a recording medium; a data extractor extracting data by a second beam incident from the recording medium; And a decryption operation unit for decrypting data using a decryption key, and a data reproduction unit for reproducing the decrypted data.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 illustrate the structure of a recording medium according to an embodiment of the present invention.

1 is a view of the recording medium viewed from above, and FIG. 2 is a cross-sectional view of the recording medium.

1 and 2, the recording medium 30 according to the embodiment of the present invention can be largely divided into three areas.

First, the first region 31 is a region in which a portion coupled with the spindle motor for rotation of the recording medium 30 is formed, and main general information of the disk to be permanently stored may be stored.

The second area 32 is a data area in which content to be recorded, such as multimedia data, is stored, and the third area 33 is an area in which new data can be rewritten.

On the other hand, the three divided areas as described above are divided the recording medium 30 for convenience or use, and the actual data may be recorded regardless of the area of the recording medium 30.

In the cross-sectional structure of the recording medium 30, the recording medium 30 may include a first protective layer 34, a recording layer 35, a first gap layer 36, and a dichroic mirror layer ( 37, the second gap layer 38, the reflective layer 39, and the second protective layer 40.

The dichroic mirror layer 37 blocks the beam 41 for recording and reproducing data, and passes the servo beam 42 for servo. Here, the beam 41 for recording and reproducing data may be a signal beam and a reference beam having a wavelength of 405 nm or 532 nm, and the servo beam 42 for servo may be a red beam having a wavelength of 650 nm.

The first protective layer 34 and the second protective layer 40 protect the recording layer 35, and the first gap layer 36 and the second gap layer 38 are the recording layer 25 and the dike. The wing mirror layer 37 and the reflection layer 39 are distinguished.

The recording layer 35 may be formed of a material such as a photopolymer, and stores data by interference of a reference beam and a signal beam.

Land and grooves are formed in the reflective layer 166 formed under the dichroic mirror layer 37. The grooves have copy protection information (CPI) by pits and spaces. : Copy Protection Information) can be recorded.

The copy protection information may be recorded in the form of a wobble pit, or in the form of a serial pit, or may be recorded in various pit forms in which a wobble pit and a serial pit are mixed.

In addition, the copy protection information may be recorded in any one of the first area, the second area, and the third area of FIG. 1, and may be recorded in each area.

Data recorded on the recording layer 25 may be encrypted by copy protection information (CPI) to prevent unauthorized copying and recorded as encrypted data. In the reflection layer 39 in which copy protection information is recorded, a decryption key capable of reproducing data encrypted by the incident red beam is read.

Regarding the method of recording the copy protection information, only a duly authorized manufacturer can recognize or use the manufacturer, and a duly non-authorized manufacturer cannot re-master the disc by digitizing the analog output again. Let's do it. Therefore, it is possible to prevent data copying.

In addition, the land and the groove of the reflective layer 39 have address information, and the incident red beam is reflected so that the servo beam can be generated.

3 is a view for explaining a configuration of a data recording and reproducing apparatus capable of storing data on a recording medium or reproducing recorded data according to an embodiment of the present invention.

Referring to FIG. 3, a data recording and reproducing apparatus according to an exemplary embodiment of the present invention includes a shutter 11 for blocking or passing a beam generated by a light source 10, and a beam beam incident from the shutter 11. The beam splitter 12 separating the path S1 of the signal beam and the path S2 of the reference beam, and the recording medium 30 on which data is recorded due to the interference between the signal beam and the reference beam. Included.

In detail, the light source 10 may be a laser diode emitting a beam having a wavelength of 405nm or 532nm, the beam splitter 12 transmits the beam by reflecting the incident beam according to the polarization direction A polarization beam splitter (PBS) for separating may be used.

In addition, the shutter 11 operates on / off to allow the beam emitted from the light source 10 to be intermittently passed.

At this time, the progress of the beam may be controlled by controlling the light source 10 on / off without providing the shutter 11. The data recording and reproducing apparatus according to the embodiment of the present invention may allow data to be stored or reproduced in units of pages at the time of recording and reproducing by the shutter 11.

In addition, the signal path processing path S1 includes an actuator 20 in which a reflection mirror 17 for changing a traveling angle of the reference beam is formed.

In detail, the reflective mirror 17 reflects the reference beam separated by the beam splitter 12 to be incident on the recording medium 16, and the actuator 20 drives the reflective mirror 17. The incident position or the incident angle of the reference beam incident on the recording medium 30 is changed.

Accordingly, the signal beam processing path S1 serves to provide the recording medium 30 with a recording or reproducing reference beam required for recording or reproducing hologram data.

In addition, the signal beam processing path S1 includes a spatial light modulator (SLM) 13 that carries input data to be recorded in the signal beam separated from the beam splitter 12.

In detail, the spatial light modulator 13 may be formed of a liquid crystal on silicon (LCoS) panel, and loads input data, that is, data stored in units of pages, in a signal beam passing through the beam separator 12. give.

The signal beam into which the data is input is incident to the recording medium 30 through the objective lens 15.

In addition, the recording medium 30 is located on an optical path where the signal beam output from the spatial light modulator 13 and the reference beam reflected from the reflection mirror 17 cross each other, and the signal beam and the reference beam The interference fringe generated by the interference of is recorded, and the interference fringe recorded by the irradiation of the reference beam is restored and output.

In addition, the data recording and reproducing apparatus according to the present invention includes an image sensor 21 for reproducing data recorded on the recording medium 30.

Specifically, the image sensor 21 is located on the optical path of the diffracted light generated when the reference beam is incident on the recording medium 30, and when restoring the interference fringe recorded on the recording medium 30, Convert it to the original electrical signal.

A complementary metal-oxide semiconductor (CMOS) sensor may be used as the image sensor 21.

Meanwhile, a laser diode 18 and a photo detector 19 may be included for the servo operation according to the movement of the recording medium 30.

The laser diode 18 may emit red light having a wavelength of 650 nm, and is provided for focusing servo, tracking servo, and tilting servo for the base isolation component of the recording medium 30.

The red light emitted from the laser diode 18 is incident on the recording medium 30 through the beam separators 22 and 23 and the objective lens 15.

As illustrated in FIG. 2, the red light is reflected through the dichroic mirror layer 37 of the recording medium 30 in the land / groove structure of the reflective layer 39. The land / groove structure enables servo operation.

Servo light reflected from the recording medium 30 passes through the objective lens 15 and the beam separators 22 and 23 and enters the photo detector 19.

Therefore, the servo operation may be performed according to the movement of the recording medium 30 from the servo light incident on the photo detector 19.

Servo operation is achieved by controlling the actuator 20 in the focusing servo circuit 24, the tracking servo circuit 25 and the tilting servo circuit 26.

Meanwhile, the copy protection information stored in the recording medium 30 may be read through the photo detector 19, and the copy protection information is used to reproduce the data read by the reference beam.

Next, the operation of the data recording and reproducing apparatus according to the present invention configured as described above will be described.

First, the laser beam generated by the light source 10 passes through the shutter 11 and is separated into a reference beam and a signal beam by the beam splitter 12.

In addition, the signal beam separated by the beam splitter 12 is incident to the spatial light modulator 13 and then enters the recording medium 30 after the data to be recorded is included in units of pages.

In addition, the reference beam separated by the beam splitter 12 is changed at a predetermined angle by the reflecting mirror 17 driven by the actuator 20 and is incident on the recording medium 30.

Then, the signal beam and the reference beam cause interference in the recording medium 30, and the interference fringes generated at this time are recorded on the recording medium 30.

After one page is recorded as described above, the next page is applied with a reference beam having a slightly different angle of the reflection mirror 17. That is, after recording the first page of data on the recording medium 30, when the laser beam generated from the light source 10 is temporarily blocked by the shutter 11 and then passed again, the angle of the reference beam is changed to a different angle. As a reference beam, a new data page is input and recorded on the recording medium 30.

Here, the reference beams are formed to be slightly different from each other by the driving of the actuator 20 so that the reference beams correspond to the respective pages, so that the reference beams are incident on the recording medium 30 at different angles. Can be.

Therefore, by repeating the process of changing the angle of the reference beam for each page recording, the hologram data can be superimposed on the recording medium 30, and a large amount of data can be recorded in the unit of the page at the same place for high capacity. Data recording becomes possible.

In addition, in order to reproduce the data recorded on the recording medium 30, only the reference beam is incident on the recording medium 30. Here, the reference beam incident on the recording medium 30 at the time of reproduction should be incident at the same angle as the reference beam incident on the recording, which may be adjusted by driving the actuator 20.

Therefore, when a reference beam having an angle equal to the recording angle of the reference beam at the time of recording is irradiated to the recording medium 30, the interference fringe recorded on the recording medium 30 diffracts the reference beam to contrast the original pixels. It is restored to a checkerboard consisting of. And, if the read image is illuminated on the image sensor 21, the original recorded data can be reproduced.

The servo operation according to the movement of the recording medium 30 during recording and reproducing of data detects the servo light generated by the red light emitted from the laser diode 18 from the recording medium 30 by the photo detector 19. By doing so. In addition, the copy protection information recorded in the reflective layer 39 of the recording medium 30 is read out by the red light.

4 is a diagram for explaining reproduction of data using copy protection information in an embodiment of the present invention.

The decryption key extractor 50 extracts the decryption key from the beam received by the photo detector 19. The data extracting unit 51 extracts data from the reproduction beam received by the image sensor 21.

The decryption operation unit 52 decrypts the encrypted data obtained by the data extraction unit 51 using the decryption key obtained by the decryption key extraction unit 50 to process the unencrypted data. . Then, the data reproducing section 53 reproduces the data processed as the unencrypted data.

Therefore, the data stored in the recording medium on which the copy protection information is recorded can be reproduced.

The present invention can prevent unauthorized copying of content by including copy protection information in a holographic data recording medium.

In addition, the present invention can process the encrypted data in the holographic data recording medium storing the copy protection information as non-encrypted data to reproduce.

Claims (8)

A recording layer in which data is recorded by interference of the signal beam and the reference beam, A reflection layer in which lands and grooves are formed and a decryption key is recorded; And a dichroic mirror layer positioned between the recording layer and the reflective layer and configured to selectively pass a beam according to the wavelength. The method of claim 1, And the copy protection information is recorded in any one of a wobble pit shape, a serial pit shape, and a pit shape in which a wobble pit and a serial pit are mixed. The method of claim 1, The dichroic mirror layer is a recording medium, characterized in that for passing the wavelength of the red light band. Obtaining a decryption key from the recording medium by the first beam; Acquiring data from the recording medium by the second beam; Decrypting the data using the decryption key; And reproducing the decoded data. The method of claim 4, wherein And controlling an incident position or an incident angle at which the second beam is incident on a recording medium by using the first beam as a servo beam. A decryption key extracting unit for extracting a decryption key by the first beam incident from the recording medium; A data extraction unit for extracting data by the second beam incident from the recording medium; A decryption operation unit to decrypt data using the decryption key; And a data reproducing unit for reproducing the decoded data. The method of claim 6, And the decryption key extracting unit extracts a decryption key from a signal input from a photo detector. The method of claim 6, The data extractor extracts data from a signal input from an image sensor.

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