KR20030079174A - Optical media written label, apparatus and method for writing label in the optical media - Google Patents

Abstract

PURPOSE: An optical recording medium recorded with a label, and an apparatus and method for recording a label on an optical recording medium are provided for users to read characters or pictures at recording and visible areas by appropriately arranging a group of recording marks at a partial area of an optical recording medium. CONSTITUTION: An optical disk is divided into a data area and an image area. The data area has a range preliminarily set and regenerative data is recorded on the data area. The image area has a range preliminarily set and visible image recording is possible on the image area. The image area is formed of a group of recording marks different from the data area in a reflecting rate.

Description

Optical record written label, apparatus and method for writing label in the optical media}

The present invention relates to an optical recording medium, an apparatus and method for operating the optical recording medium, and more particularly, to an optical recording medium having a label readable by a human eye, and an apparatus and method for recording a label on the optical recording medium. It is about.

In general, a DVD disc is a storage medium capable of storing data equivalent to 7 times the size of a CD, having the same size as a compact disc (CD) having a diameter of 12 cm and a thickness of 1.2 mm. For reference, a CD can hold 74 minutes of data, which is about 688MB in size.However, a disc for a DVD has the same size as a CD, depending on whether it is single-sided, double-sided, single-layered or multi-layered. You can store up to 17GB in GB.

Such optical recording media such as CDs or DVDs are useful media for recording and storing digital data, and their spread is gradually expanding. If an average user wanted to leave a label on a blank disk after writing the data on a blank disk, the user had to write a note using a writing instrument or attach a printed sheet to the opposite side of the recording surface.

SUMMARY OF THE INVENTION The present invention has been made in an effort to provide an optical recording medium in which a label desired by a user is recorded in an image area and is divided into a data area and an image area.

Another technical problem to be solved by the present invention is to provide an apparatus for recording a label on an optical recording medium for recording an image desired by a user in an image area in an optical recording medium divided into a data area and an image area.

Another technical problem to be solved by the present invention is to provide a method of recording a label on an optical recording medium for recording an image desired by a user in an image area in an optical recording medium divided into a data area and an image area.

1 is a view showing an optical recording medium on which a label according to the present invention is recorded.

2 is a block diagram showing the configuration of an apparatus for recording a label on an optical recording medium according to the present invention.

3 is a flowchart showing the operation of the method of recording a label on the optical recording medium according to the present invention.

4 is a graph showing a difference between reflectances of areas where labels are recorded and areas where labels are not.

5 is a view showing another embodiment of an optical recording medium in which a label is recorded.

6 is a block diagram showing the configuration of another embodiment of an apparatus for recording a label on an optical recording medium.

7 is a flowchart showing the operation of another embodiment of a method of recording a label on an optical recording medium.

An optical recording medium on which a label is recorded for solving the technical problem to be solved by the present invention comprises: a data area having a preset range and storing reproducible data; And an image area having a preset range and capable of visible image recording.

In the present invention, the data area and the image area are characterized by different optical characteristics.

In the present invention, the optical characteristic is characterized by varying the number, type, thickness, etc. of the multilayer film on each substrate of the data area and the image area when manufacturing the optical recording medium.

In the present invention, when the optical recording medium can be recorded once, at least two organic Dye films and reflective films are formed on the substrate of the optical recording medium.

In the present invention, when the optical recording medium is capable of recording once, the image area is characterized in that the reflectance of the data area is changed by the state change of the Dye and the deformation of the substrate.

In the present invention, when the optical recording medium can be repeatedly recorded, at least four or more dielectric films, recording films, dielectric films, and reflective films are formed on the substrate of the optical recording medium.

In the present invention, when the optical recording medium is capable of repeatable recording, the image region is characterized in that the phase change occurs from crystalline to amorphous in the recording layer on the substrate, whereby the reflectance is changed.

In the present invention, the data area is located inside the image area in consideration of compatibility with an optical recording medium composed only of the data area.

In the present invention, when the optical recording medium has a single-layered double-sided structure, the first surface of the two surfaces is divided into the data area, and the remaining second surface is divided into the image area or vice versa.

In the present invention, when the optical recording medium has a single-layered double-sided structure, each of the two sides is divided into the data area and the image area.

In the present invention, when the optical recording medium has a two-layer cross-sectional structure, the first layer of the two layers is divided into the data area, and the remaining second layer is divided into the image area and vice versa.

In the present invention, when the optical recording medium has a two-layer cross-sectional structure, each of the two layers is divided into the data area and the image area.

In the present invention, when the optical recording medium has a two-layer double-sided structure, any one or both of the two layers or both surfaces is divided into the data area or the image area.

An apparatus for recording a label on an optical recording medium for solving another technical problem to be solved by the present invention comprises an image in the image area in an optical recording medium comprising a data area in which playable data is recorded and an image area in which image recording is possible. An apparatus for recording an image, comprising: image processing means for editing and encoding a size, color, shape, etc. of an image to be recorded in the preset image area; And image recording means for modulating the encoded image to record in an image area of the optical recording medium.

In the present invention, the apparatus further comprises discriminating means for discriminating the type of the optical recording medium by using the track information of the optical recording medium.

In the present invention, the image processing means edits and encodes an image to be recorded in the image area located outside the data area when the optical recording medium determined by the discriminating means has a single-sided tomographic structure.

In the present invention, when the optical recording medium determined by the discriminating means has a single-layered double-sided structure, the image processing means edits and encodes an image to be recorded on one of the two sides.

In the present invention, when the optical recording medium determined by the discriminating means has a single-layered double-sided structure, the image processing means edits and encodes an image to be recorded in the image area located outside the data area for each of the two sides. It is characterized by.

In the present invention, when the optical recording medium determined by the discriminating means has a two-layered cross-sectional structure, the image processing means is characterized by editing and encoding an image to be recorded on one of the two layers.

In the present invention, when the optical recording medium determined by the discriminating means has a two-layered cross-sectional structure, the image processing means edits and encodes an image to be recorded in the image region located outside the data region for each of the two layers. It is characterized by.

In the present invention, when the optical recording medium determined by the discriminating means has a two-layered double-sided structure, the image processing means edits and encodes an image to be recorded on either or both of the two-layered or both-sided surfaces. do.

In the present invention, the apparatus further comprises signal generating means for generating a synchronization signal for aligning the beginning of an image to be recorded in the image area.

In the present invention, the signal generating means generates a synchronizing signal using wobble information on which predetermined information of the optical recording medium is recorded.

In the present invention, the signal generating means generates a synchronizing signal by using a rotation detection signal of a motor for rotating the optical recording medium.

In the present invention, the image editing means can combine the colors of the image to be recorded according to the number, type and thickness of the multilayer film of the image area.

According to another aspect of the present invention, there is provided a method of recording a label on an optical recording medium. The method includes a data area in which reproducible data is recorded and an image area in which an image can be recorded. A method of recording an image, the method comprising: (a) determining a type of the optical recording medium; (b) editing and encoding a size, color, shape, etc. of an image to be recorded in the preset image area; And (c) modulating the encoded image and recording in the image area of the optical recording medium.

In the present invention, when the optical recording medium is determined to have a single-sided tomographic structure in step (a), the image to be recorded in the image area located outside the data area is edited and encoded in step (b). It is done.

In the present invention, when the optical recording medium is determined to have a single-layered double-sided structure in step (a), the image to be recorded on one of the two sides is edited and encoded in step (b).

In the present invention, when the optical recording medium is determined to have a single-layered double-sided structure in step (a), the image to be recorded in the image area located outside the data area for each of the two sides in step (b) is edited. And encoding.

In the present invention, when the optical recording medium is determined to have a two-layered cross-sectional structure in step (a), the image to be recorded on one of the two layers is edited and encoded in step (b).

In the present invention, when the optical recording medium is determined to have a two-layered cross-sectional structure in step (a), an image to be recorded in the image area located outside the data area for each of the two layers in step (b). It is characterized in that for editing and encoding.

In the present invention, if the optical recording medium is determined to have a double-layered double-sided structure in step (a), the image to be recorded on either or both of the layers or both sides is edited in step (b). It is characterized by encoding.

In the present invention, the color of the image to be recorded may be combined according to the number, type and thickness of the multilayer film of the image area in the step (b).

In the present invention, in the step (c), before the image recording, the image recording start synchronization is synchronized using wobble information in which predetermined information of the optical recording medium is recorded.

In the present invention, the image recording start synchronization is achieved by using the rotation detection signal of the motor which rotates the optical recording medium before the image recording in the step (c).

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

1 is a view showing an optical recording medium on which a label according to the present invention is recorded.

Fig. 2 is a block diagram showing the configuration of an apparatus for recording a label on an optical recording medium according to the present invention. The optical disc 200, pickup & motor 201, signal processor 202, disc discriminator 203, An image synchronization signal generator 204, an image editing unit 205, an image encoding unit 206, and a Write Strategy 207 are provided.

3 is a flowchart illustrating an operation of a method of recording a label on an optical recording medium according to the present invention, in which an optical disc is inserted and a type of the optical disc is determined (300), and the image to be recorded in a preset image area Editing (301), encoding the edited image (302), modulating the encoded image for accurate mark recording and then recording it to the optical disc (303), identifying the optical disc on which the image is recorded Step 304 is made up.

4 is a graph showing a difference between reflectances of areas where labels are recorded and areas where labels are not.

Next, the present invention will be described in detail with reference to FIGS. 1 to 4.

The optical recording medium, i.e., the optical disc shown in FIG. 1A, is divided into a data area in which a reproducible data is recorded, and an image area in which image recording is possible, having a preset range. The image area of the optical disc can be read by the human eye. The image area that can be read by the human eye is composed of a group of recording marks having different reflectances from the data area.

The optical characteristics of the data region and the optical characteristics of the image region are different from each other. The optical characteristics of the data region are determined so as to obtain optimal characteristics when recording / reproducing in the drive, and the optical characteristics of the image region are optimal when recording / reproducing in the drive. The characteristics of are not obtained but are determined to be suitable for reading images with the human eye. In the data area and the image area, the number, type, thickness, and the like of the multilayer film formed on the polycarbonate substrate are different so that the optical characteristics are different.

The configuration varies depending on whether or not the optical disk is rewritable. When the optical disk can only write once, at least two layers of an organic dye and a reflective layer are formed on the polycarbonate substrate when the optical disk has a single layer structure. However, in the case of an optical disk having a double layer structure, the multilayer film configuration can be changed. The optical disc, which can be written once, changes the data area and reflectance due to the change of the Dye state and the deformation of the substrate when the image is recorded in the image area, and Ag, Au, Al, or an alloy thereof is used as the reflective layer.

In the case of an optical disk capable of repeatable recording, at least four layers of a dielectric film, a recording film, a dielectric film, and a reflective film are formed on a polycarbonate substrate when the optical disk has a single layer structure. However, in the case of an optical disk having a two-layer structure, a change in the multilayer film configuration is possible. Optical discs capable of repeatable recording have a phase change from crystalline to amorphous in the recording layer when the image is recorded in the image area, and thus reflectance is changed. Alloys such as Ge-Sb-Te and Ag-In-Sb-Te are used as the recording film, ZnS-Sio2 is used as the dielectric film, and Al alloy, Au alloy and the like are used as the reflective layer.

The optical disk has different optical characteristics depending on the configuration of the multilayer film formed on the polycarbonate substrate. In the case of an optical disc capable of repeating reproduction, at least four layers of a dielectric film, a recording film, a dielectric film, and a reflective film are formed on a polycarbonate substrate. Thus, for example, when forming a multilayer thin film on a polycarbonate substrate, a portion of a data region or an image region is covered with a mask (not shown), a dielectric film having a predetermined thickness is formed only on the other portion, and the mask is removed to remove the dielectric having a remaining thickness. When the film, the recording film, and the dielectric film reflective film are formed, the optical characteristics of the data area and the image area may vary.

Using this method, the data area can achieve optimal recording / playback characteristics, and the image area can visually increase the contrast of the image. By repeating this masking process several times, the visual contrast of each region can be obtained even within the image region. If the thickness uniformity of the thin film is given when the multilayer thin film is formed, the visual contrast within the image region can be reduced. Gradual changes can be achieved.

Label, that is, a graph showing the difference in reflectance between an image area where an image is recorded and an area where an image is not recorded, wherein Ra is an area of the image area according to the thickness of the first dielectric film when there is a dielectric film, a recording film, a dielectric film, or a reflecting film under the incident substrate. The reflectance, Rc, is the reflectance of the unrecorded area, and ΔR is the difference between the reflectances of the two areas. Changing the thickness of the dielectric film from about 50 nm to 105 nm or from 105 nm to 150 nm can change the reflectance difference from about 8% to 18%. The graph of FIG. 4 is an embodiment, and when the thicknesses of other thin films are also changed, a larger contrast difference may be obtained.

The position of the data area and the position of the image area which are predetermined according to the type of the optical disc are implemented differently.

First, in the case of an optical disk having a single side sing layer structure, as shown in FIG. 1A, the optical disk is divided into a predetermined data area and a predetermined image area. In consideration of compatibility with media embodied only in the data area, the data area is placed inside and the image area is placed outside.

In the case of an optical disk having a double side single layer structure, as illustrated in FIG. 1B, a first side of both sides may be divided into a data region, and the other second side may be divided into an image region and vice versa. In addition, as shown in FIG. 1A, each of the two surfaces may be divided into a data area and an image area.

In the case of an optical disk having a single side double layer structure, as shown in FIG. 1B, a first layer of both layers may be divided into a data region, and the remaining second layer may be divided into an image region and vice versa. . In addition, both layers may be divided into a data area and an image area.

In the case of a double-sided double layered disc, as shown in FIG. 1B, either or both of the layers or both sides may be divided into a data region or an image region.

Referring to Fig. 2, an apparatus for recording a label on an optical recording medium according to the present invention will be described. The optical disc 200 is divided into a predetermined data area and an image area as described above.

The pickup & motor 201 extracts a signal to be reproduced from the optical disc 200 or records an image on the optical disc 200.

The signal processor 202 modulates, signals, and outputs various signals output from the pickup & motor 201 as signals to be reproduced.

The disc determining unit 203 determines the optical disc 200 from the track information among the signals output from the signal processing unit 202. The disc discrimination unit 203 determines whether the optical disc 200 is a disc which can be recorded once or a disc which can be repeatedly recorded from the disc information signal output from the signal processing unit 202, and the optical disc 200 has a single-sided structure. It is discriminated whether it is a single-sided disc, a double-sided single-sided disc, a single-sided double-sided disc, or a double-sided double-sided disc.

The image synchronizing signal generator 204 generates a synchronizing signal for aligning the beginning of the image to be recorded in the image area. The image synchronizing signal generator 204 generates an image synchronizing signal using the wobble information of the optical disk 200 or a rotation detection signal of a motor that rotates the optical disk 200 output from the pickup & motor 201. To generate an image synchronization signal.

The image editing unit 205 edits the size, color, shape, and the like of the image to be recorded in the predetermined image area. The image editing unit 205 indicates whether the optical disc 200 is a disc which can be recorded once, a disc which can be repeatedly recorded, and whether the optical disc 200 is a single-sided single-sided disc, a double-sided single-sided disc, a short-lived double-sided disc, or a double-sided double-sided disc. The image size can be determined according to the recognition. This is because the optical disc 200 of the present invention has a preset range of data area and image area. The image editing unit 205 may select a desired color by combining the colors of the image to be recorded according to the number, type and thickness of the multilayer film in the image area.

The image editing unit 205 edits the color, composition, and size of an image to be recorded in an image area located outside the data area when the determined optical disc 200 has a single-sided tomographic structure. The image editing unit 205 edits the color, composition, and size of an image to be recorded on one of the two sides when the determined optical disc 200 has a single-layered double-sided structure, or the image editing unit 205 in the image area located outside the data area for each of the two sides. Edit the color, composition, and size of the image to be recorded. The image editing unit 205 edits the color, composition, and size of an image to be recorded on one of the two layers when the determined optical disc 200 has a two-layered cross-sectional structure, or on the image region located outside the data area for each of the two layers. Edit the color, composition, and size of the image to be recorded. The image editing unit 205 edits the color, composition, and size of an image to be recorded on either or both of two layers or both sides when the optical disc 200 has a two-layer double-sided structure.

The image encoding unit 206 encodes the image edited by the image editing unit 205. The image encoding unit 206 encodes the edited image so that the laser beam can continuously record while following the track.

Write Strategy 207 modulates for accurate mark writing of the encoded image. The modulated image is recorded on the optical disc 200 via the pickup & motor 201 by a synchronization signal that matches the image start area generated by the image synchronization signal generator 204.

When the image recording on the optical disc 200 is confirmed after confirmation, the recorded image can be visually viewed.

3 is a view for explaining a method of recording a label on an optical recording medium according to the present invention, in which an optical disk is inserted and the type of the optical disk is determined (step 300). The optical disc 200 is determined from the track information output from the optical disc 200. The optical disc 200 determines whether the optical disc 200 is a disc which can be recorded once or a disc which can be repeatedly recorded, and the optical disc 200 It is discriminated whether it is a single-sided single-sided disc, a double-sided single-sided disc, a single-sided double-sided disc or a double-sided double-sided disc.

If the type of the optical disc 200 is determined, the image to be recorded in the preset image area is edited (step 301). The image editing unit 205 edits the size, color, shape, and the like of the image to be recorded in the predetermined image area. The image editing unit 205 indicates whether the optical disc 200 is a disc which can be recorded once, a disc which can be repeatedly recorded, and whether the optical disc 200 is a single-sided single-sided disc, a double-sided single-sided disc, a short-duplex double-sided disc or a double-sided double-sided disc. The image size can be determined according to the recognition. This is because the optical disc 200 of the present invention has a preset range of data area and image area. The image editing unit 205 may select a desired color by combining the colors of the image to be recorded according to the number, type, and thickness of the multilayer film of the image area. In the case of a structure, the color, composition, and size of an image to be recorded in an image area located outside the data area are edited.

The image editing unit 205 edits the color, composition, and size of an image to be recorded on one of the two sides when the determined optical disc 200 has a single-layered double-sided structure, or the image editing unit 205 in the image area located outside the data area for each of the two sides. Edit the color, composition, and size of the image to be recorded. The image editing unit 205 edits the color, composition, and size of an image to be recorded on one of the two layers when the determined optical disc 200 has a two-layered cross-sectional structure, or on the image region located outside the data area for each of the two layers. Edit the color, composition, and size of the image to be recorded. The image editing unit 205 edits the color, composition, and size of an image to be recorded on either or both of two layers or both sides when the optical disc 200 has a two-layer double-sided structure.

When editing is completed in the color, composition, and size of the image, the edited image is encoded (step 302). The image encoding unit 206 encodes the edited image so that the laser beam can continuously record while following the track.

The encoded image is modulated for accurate mark recording and then recorded on the optical disc (step 303). Write Strategy 207 modulates for accurate mark writing of the encoded image. The modulated image is recorded on the optical disc 200 via the pickup & motor 201 by a synchronization signal that matches the image start area generated by the image synchronization signal generator 204.

The optical disc 200 on which the image is recorded is checked (step 304). When the image recording on the optical disc 200 is confirmed after completion, the recorded image can be visually viewed.

5 is a view showing another embodiment of an optical recording medium in which a label is recorded.

Fig. 6 is a block diagram showing the configuration of another embodiment of a device for recording a label on an optical recording medium. The optical disc 600, pickup & motor 601, signal processor 602, disc discriminator 603, and image are shown in Figs. A synchronization signal generator 604, an image editing unit 605, an image encoding unit 606, and a Write Strategy 607 are included.

FIG. 7 is a flowchart showing an operation of another embodiment of a method of recording a label on an optical recording medium. The method includes inserting an optical disc and determining the type of the optical disc (700), and the lead-in area of the determined optical disc. Reading the data area and the image area information or recording the newly set data area and the image area information in the lead-in area (701), editing the image to be recorded in the variable image area (702), Encoding the edited image (703), modulating the encoded image for accurate mark recording and then recording (704) on the optical disc, and identifying (705) the optical disc on which the image is recorded.

Next, the present invention will be described in detail with reference to Figs.

The optical recording medium, that is, the optical disc shown in FIG. 5A is divided into a data area in which a reproducible data is recorded and a reproducible data and an image area in which image recording is possible. The image area of the optical disc can be read by the human eye. The distinguishing information of the data area and the image area is recorded in the lead-in area in the disc.

The position of the data area and the position of the image area are implemented differently according to the type of optical disc. First, in the case of an optical disk having a single layer structure, as shown in FIG. 5A, the data disk is divided into a variable data area and a variable image area. In consideration of compatibility with media embodied only in the data area, the data area is placed inside and the image area is placed outside. The image area is placed outside, i. E. In the lead-out area.

In the case of an optical disk having a double side single layer structure, as illustrated in FIG. 1B, a first side of both sides may be divided into a data region, and the other second side may be divided into an image region and vice versa. In addition, as shown in FIG. 1A, each of the two surfaces may be divided into a data area and an image area. The disc area division information is recorded in the lead-in area.

In the case of an optical disk having a single side double layer structure, as shown in FIG. 1B, a first layer of both layers may be divided into a data region, and the remaining second layer may be divided into an image region and vice versa. . In addition, both layers may be divided into a data area and an image area. The disc area division information is recorded in the lead-in area.

In the case of a double-sided double layered disc, as shown in FIG. 1B, either or both of the layers or both sides may be divided into a data region or an image region. The disc area division information is recorded in the lead-in area.

Referring to Fig. 6, a device for recording a label on an optical recording medium according to the present invention will be described. The optical disc 600 is divided into a data area and an image area that are variable as described above.

The pickup & motor 601 extracts a signal to be reproduced from the optical disc 600 or records an image on the optical disc 600.

The signal processing unit 602 modulates, signals, and outputs various signals output from the pickup & motor 601 as signals to be reproduced.

The disc determining unit 603 determines the optical disc 600 from the track information among the signals output from the signal processing unit 606. The disc discrimination unit 603 determines whether the optical disc 600 is a disc which can be recorded once or a disc which can be repeatedly recorded from the disc information signal output from the signal processing unit 606, and the optical disc 600 has a single-sided cross section. It is discriminated whether it is a single-sided disc, a double-sided single-sided disc, a single-sided double-sided disc, or a double-sided double-sided disc.

The image synchronization signal generator 604 generates a synchronization signal for aligning the beginning of the image to be recorded in the image area. The image synchronizing signal generator 604 generates an image synchronizing signal using the wobble information of the optical disk 600 or rotates a detection signal of a motor for rotating the optical disk 600 output from the pickup & motor 601. To generate an image synchronization signal. If there is a header such as sector synchronization in the optical disc 600, the synchronization signal can be generated using the header.

The image editing unit 605 reads the determined lead-in area of the optical disc 600, reads the data and the range of the image area, and then edits the size, brightness, etc. of the image to be recorded. The image editing unit 605 adjusts the brightness of an image to be recorded using mark density. To adjust the mark density, use Write Strategy (606) to adjust the shape of the marked mark. The image editing unit 605 indicates whether the optical disc 600 is a disc which can be recorded once, a disc which can be repeatedly recorded, and whether the optical disc 600 is a single-sided single-sided disc, a double-sided single-sided disc, a short-duplex double-sided disc, or a double-sided double-sided disc. Edit the image to record according to your perception. Since the optical disc 600 has a plurality of different recording layers, each layer has a different recording film color, and if used appropriately, the color of the image to be recorded can be selected.

The image editing unit 605 edits an image to be recorded in an image area located outside the data area when the determined optical disc 600 has a single-sided tomographic structure. The image editing unit 605 edits an image to be recorded on one of both sides when the determined optical disc 600 has a single-layered double-sided structure, or edits an image to be recorded in an image area located outside the data area for each of the two sides. . The image editing unit 605 edits an image to be recorded on one of the two layers when the determined optical disc 600 has a two-layered cross-sectional structure, or edits an image to be recorded in an image region located outside the data area for each of the two layers. . The image editing unit 605 edits an image to be recorded on either or both of two layers or both sides when the optical disc 600 has a two-layer double-sided structure.

The image encoder 606 encodes the image edited by the image editor 605. The image encoding unit 606 allows the laser beam to continuously record while following the track, and encodes for the density and intensity of the recording signal.

Write Strategy 606 modulates for accurate mark writing of the encoded image. The modulated image is recorded while following the track on the optical disc 600 via the pickup & motor 601 by a synchronization signal that matches the image start area generated by the image synchronization signal generator 604.

When the image recording on the optical disc 600 is confirmed after completion, the recorded image can be visually viewed.

7 is a view for explaining a method of recording a label on an optical recording medium according to the present invention, in which an optical disk is inserted and the type of the optical disk is determined (step 700). The optical disc 600 is discriminated from the track information output from the optical disc 600. The optical disc 600 determines whether the optical disc 600 is a disc which can be recorded once or a disc which can be repeatedly recorded, and the optical disc 600 It is discriminated whether it is a single-sided single-sided disc, a double-sided single-sided disc, a single-sided double-sided disc or a double-sided double-sided disc.

When the type of the optical disc 600 is determined, the lead-in area of the optical disc 600 is read to check the data area and the image area information, or the data area and the image area information to be newly set are recorded in the lead-in area (step 701). ).

After checking the lead-in area, an image to be recorded in the image area is edited (step 702). The image editing unit 605 reads the determined lead-in area of the optical disc 600, reads the data and the range of the image area, and then edits the size, brightness, etc. of the image to be recorded. The image editing unit 605 adjusts the brightness of an image to be recorded using mark density. To adjust the mark density, use Write Strategy (606) to adjust the shape of the marked mark. The image editing unit 605 indicates whether the optical disc 600 is a disc which can be recorded once, a disc which can be repeatedly recorded, and whether the optical disc 600 is a single-sided single-sided disc, a double-sided single-sided disc, a short-duplex double-sided disc, or a double-sided double-sided disc. Edit the image to record according to your perception. Since the optical disc 600 has a plurality of different recording layers, each layer has a different recording film color, and if used appropriately, the color of the image to be recorded can be selected.

The image editing unit 605 edits an image to be recorded in an image area located outside the data area when the determined optical disc 600 has a single-sided tomographic structure. The image editing unit 605 edits an image to be recorded on one of both sides when the determined optical disc 600 has a single-layered double-sided structure, or edits an image to be recorded in an image area located outside the data area for each of the two sides. . The image editing unit 605 edits an image to be recorded on one of the two layers when the determined optical disc 600 has a two-layered cross-sectional structure, or edits an image to be recorded in an image region located outside the data area for each of the two layers. . The image editing unit 605 edits an image to be recorded on either or both of two layers or both sides when the optical disc 600 has a two-layer double-sided structure.

When the image editing is completed, the edited image is encoded (step 703). The image encoding unit 606 allows the laser beam to continuously record while following the track, and encodes for the density and intensity of the recording signal.

The encoded image is modulated for accurate mark recording and then recorded on the optical disc (step 704). Write Strategy 607 modulates for accurate mark writing of the encoded image. The modulated image is recorded on the optical disc 600 via the pickup & motor 601 by a synchronization signal that matches the image start area generated by the image synchronization signal generator 604.

The optical disc 600 on which the image is recorded is checked (step 705). When the image recording on the optical disc 600 is confirmed after completion, the recorded image can be visually viewed.

The present invention is not limited to the above-described embodiments and can be modified by those skilled in the art within the spirit of the invention.

As described above, according to the present invention, by appropriately disposing a group of recording marks in a portion of an optical recording medium, a character or picture that can be read by the human eye can be recorded from the difference in reflectance between the region where data is recorded and the region where the data is not. And can be read in the visible area to create the effect of increasing the user's buying motivation.

Claims (35)

A data area having a preset range and in which reproducible data is recorded; And An optical recording medium having a preset range and comprising an image area capable of visible image recording. The optical recording medium of claim 1, wherein the data area and the image area have different optical characteristics. The method of claim 2, wherein the optical characteristic is And varying the number, type, thickness, etc. of the multilayer film on each of the substrates of the data area and the image area during manufacture of the optical recording medium. The optical recording medium according to claim 1, wherein when the optical recording medium is capable of recording once, at least two organic Dye films and reflective films are formed on the substrate of the optical recording medium. The optical recording medium according to claim 4, wherein when the optical recording medium is capable of recording once, the image area is changed in reflectance from the data area due to a change in the state of the dye and the deformation of the substrate. The optical recording medium according to claim 1, wherein when the optical recording medium is capable of repeating recording, at least four layers of dielectric films, recording films, dielectric films, and reflective films are formed on the substrate of the optical recording medium. 2. The optical recording medium according to claim 1, wherein when the optical recording medium is capable of repeating recording, the image area is changed from crystalline to amorphous in the recording layer on the substrate so that the reflectance is changed. The optical recording medium of claim 1, wherein the data area is located inside the image area in consideration of compatibility with an optical recording medium consisting only of the data area. The optical recording medium of claim 1, wherein the optical recording medium has a single-layered double-sided structure. An optical recording medium characterized by dividing a first surface of the two surfaces into the data area and a remaining second surface of the image area or vice versa The optical recording medium of claim 1, wherein the optical recording medium has a single-layered double-sided structure. An optical recording medium, each of which is divided into the data area and the image area The optical recording medium of claim 1, wherein the optical recording medium has a two-layered cross-sectional structure. An optical recording medium, wherein the first layer of the two layers is divided into the data area, and the remaining second layer is divided into the image area and vice versa. The optical recording medium of claim 1, wherein the optical recording medium has a two-layered cross-sectional structure. And dividing each of the two layers into the data area and the image area. The optical recording medium of claim 1, wherein the optical recording medium has a double-sided double-sided structure. And dividing either or both of the layers or both sides into the data area or the image area. An apparatus for recording an image in an image area in an optical recording medium comprising a data area in which reproducible data is recorded and an image area in which image can be recorded Image processing means for editing and encoding the size, color, shape, and the like of an image to be recorded in the preset image area; And And image recording means for modulating the encoded image to record in an image area of the optical recording medium. 15. The device of claim 14, wherein the device is And discriminating means for discriminating the type of the optical recording medium by using the track information of the optical recording medium. 16. The apparatus according to claim 15, wherein the image processing means edits and encodes an image to be recorded in the image region located outside the data region when the optical recording medium determined by the discriminating means has a single-sided tomographic structure. Device. 16. The apparatus according to claim 15, wherein the image processing means edits and encodes an image to be recorded on one of the two sides when the optical recording medium determined by the discriminating means has a single-layered double-sided structure. 16. The apparatus according to claim 15, wherein when the optical recording medium determined by the discriminating means has a single-layered double-sided structure, the image processing means edits and encodes an image to be recorded in the image area located outside the data area for each of the two sides. Device characterized in that. 16. The apparatus according to claim 15, wherein the image processing means edits and encodes an image to be recorded on one of the two layers when the optical recording medium determined by the discriminating means has a two-layered cross-sectional structure. 16. The apparatus according to claim 15, wherein when the optical recording medium determined by the discriminating means has a two-layered cross-sectional structure, the image processing means edits and encodes an image to be recorded in the image region located outside the data region for each of the two layers. Device characterized in that. 16. The apparatus according to claim 15, wherein the image processing means edits and encodes an image to be recorded on either or both of the layers or both sides when the optical recording medium determined by the discriminating means has a two-layer double-sided structure. Device. 15. The device of claim 14, wherein the device is And signal generating means for generating a synchronizing signal for aligning the beginning of an image to be recorded in said image area. The method of claim 22, wherein the signal generating means And a synchronizing signal is generated using wobble information on which predetermined information of the optical recording medium is recorded. The method of claim 22, wherein the signal generating means And a synchronization signal is generated using a rotation detection signal of a motor for rotating the optical recording medium. 15. The apparatus according to claim 14, wherein in said image editing means And a color of an image to be recorded according to the number, type, and thickness of the multilayer film of the image area. A method of recording an image in an image area in an optical recording medium comprising a data area in which reproducible data is recorded and an image area in which image can be recorded, (a) determining a type of the optical recording medium; (b) editing and encoding a size, color, shape, etc. of an image to be recorded in the preset image area; And (c) modulating the encoded image and recording it in an image area of the optical recording medium. 27. The method of claim 26, wherein if the optical recording medium is determined to have a single-sided tomographic structure in step (a), editing and encoding an image to be recorded in the image area located outside the data area in step (b). How to feature. 27. The method of claim 26, wherein if the optical recording medium is determined to have a single-layered double-sided structure in step (a), the image to be recorded on one side of the two sides is edited and encoded in step (b). 27. The image recording apparatus according to claim 26, wherein when the optical recording medium is determined to have a single-layered double-sided structure in step (a), an image to be recorded in the image area located outside the data area for each of the two sides in step (b) Method for editing and encoding. 27. The method of claim 26, wherein if the optical recording medium is determined to have a two-layered cross-sectional structure in step (a), the image to be recorded on one of the two layers is edited and encoded in step (b). Way. 27. The apparatus according to claim 26, wherein if the optical recording medium is determined to have a two-layered cross-sectional structure in step (a), it is to be recorded in the image area located outside of the data area for each of the two layers in step (b). Editing and encoding the image. The image recording medium according to claim 26, wherein if the optical recording medium is determined to have a double-sided double-sided structure in step (a), the image to be recorded on either or both of the layers or both sides is edited in step (b). And encoding. 27. The method of claim 26, wherein in the step (b), the colors of the images to be recorded can be combined according to the number, type, and thickness of the multilayer film of the image area. 27. The method according to claim 26, wherein in step (c), image recording start synchronization is synchronized using wobble information in which predetermined information of the optical recording medium is recorded before image recording. 27. The method according to claim 26, wherein in the step (c), the image recording start synchronization is synchronized using a rotation detection signal of a motor that rotates the optical recording medium before image recording.