JP2006019018A - Method for forming image on label side of optical disk and optical disk device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To form an image on a label side of an optical disk using a laser beam of an optical disk device. <P>SOLUTION: A visible light characteristic-varying layer formed of a photosensitive material, thermosensitive material, and the like is formed in a location which can be viewed from a label side of the optical disk. The optical disk is set on the turntable of the optical disk device while the label side is directed downward. The optical disk is made still, and an optical pickup is moved in the radial direction of the optical disk and in the tangential direction of the tracks perpendicular to the radial direction of the optical disk. The visible light characteristic-varying layer is irradiated with a laser beam emitted from the optical pickup in synchronization with the movement of the optical pickup by modulating the laser beam power according to the image data for a character, a picture, and the like of which the image is going to be formed. The image applicable to the label side is formed by varying the visible light characteristic of the visible light characteristic-varying layer by the irradiation of the laser beam. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an optical disk label surface image forming method and an optical disk device, which can form an image on a label surface using laser light from the optical disk device. The image is formed by moving in two orthogonal directions along the plane.

  In a recordable optical disc, information (title and the like) related to the recorded content is entered along with the optical disc by the user so that the content recorded on the optical disc can be visually confirmed. In this case, in the case of a single-sided optical disk that is handled as a single disk without being stored in a cartridge such as a CD-based optical disk {CD-R (CD recordable), CD-RW (CD rewritable), etc.}, a pen is directly placed on the label surface of the optical disk. It is generally done to write. As another method, information on recorded contents is edited on a personal computer, printed on a label by a printer, and pasted on a label surface.

In the method of writing directly on the disc label surface with a pen, the recording layer may be damaged if writing with a strong force using a hard pen or the like. Further, in the method of printing on a label with a printer, a printer is separately required.
SUMMARY OF THE INVENTION The present invention has been made in view of the above points. The label surface of an optical disk that can form an image on the label surface using laser light from an optical disk device, and does not require writing with a pen or printing with a printer. An image forming method and an optical disc apparatus are to be provided.

  According to the label surface image forming method of the present invention, a visible light characteristic {color (hue, lightness, saturation) from the label surface side by irradiation of laser light from the label surface side at a position visible from the label surface side of the optical disc. , Spectrum, reflectance, transmittance, light scattering, etc.} are changed, and the optical disc is set on the turntable of the optical disc apparatus with its label surface facing the laser beam incident side, The optical disk and the laser beam emitted from the optical pickup are relatively moved along the surface of the optical disk, and the laser beam emitted from the optical pickup in synchronism with the relative movement is used to form an image. Modulating according to image data such as a picture and irradiating the visible light property changing layer from the label surface side, the visible light property of the visible light property changing layer by the irradiation By reduction, and forms an image corresponding to the label surface. According to this label surface image forming method, the visible light characteristic changing layer formed at a position visible from the label surface side of the optical disk is irradiated with the laser light of the optical disk device to change the visible light characteristic of the layer, and Since images such as characters and pictures corresponding to the label surface are formed, writing with a pen and printing with a printer can be made unnecessary.

  In the label surface image forming method of the present invention, for example, the laser beam can be a laser beam having a predetermined power or higher. According to the label surface image forming method of the present invention, the optical disk is stationary, and the optical pickup is moved in the radial direction of the optical disk and the track tangential direction perpendicular to the radial direction of the optical disk to form an image. It is.

  An optical disc apparatus according to the present invention includes a relative movement mechanism that relatively moves an optical disc set on a turntable with a label surface facing a laser beam incident side and a laser beam emitted from an optical pickup along the surface of the optical disc, A laser modulation circuit that modulates a laser beam emitted from an optical pickup, the relative movement mechanism, and a control circuit for the laser modulation circuit, wherein the control circuit controls the relative movement mechanism to control the optical disc and the optical disc. A laser beam emitted from the optical pickup by moving the laser beam relative to each other and controlling the laser modulation circuit according to the relative movement and image data such as characters and pictures to be formed on the label surface of the optical disc. The light is modulated with the image data, and the corresponding image is formed in a place where it can be seen from the label side of the optical disc. By irradiation of the laser beam and performs control of the image formed on the visible light characteristic changing layer to change the visible light characteristic.

  The optical disc apparatus according to the present invention includes a radial feed drive device in which the relative movement mechanism moves the optical pickup in the radial direction of the optical disc, and a track tangential direction of the optical disc perpendicular to the radial movement direction. And a track tangential feed driving device for moving the optical disc and the laser beam by controlling the drive devices while the turntable is stationary. An optical disc apparatus according to the present invention includes a radial position detection device for detecting the optical disc radial position of the optical pickup, and a track tangential direction for detecting an optical disc track tangential position orthogonal to the moving direction of the optical pickup in the optical disc radial direction. A position detection device is further provided, and an image of a character, a picture, or the like to be imaged on the detection position of both the position detection devices and the label surface of the optical disc by the control circuit emitting laser light emitted from the optical pickup. Control to modulate according to data can be performed. Further, the position information of the image data may be represented by coordinate data by a combination of an optical disc radial position and an optical disc track tangential position orthogonal to the moving direction of the optical pickup in the optical disc radial direction. The control circuit may turn off the tracking servo and turn on or off the focus servo to perform relative movement between the optical disc and the laser beam. The control circuit may control to vibrate the tracking actuator of the optical pickup while relatively moving the optical disc and the laser beam. The optical disk apparatus of the present invention is an optical disk recording apparatus for a single-sided optical disk such as a CD-based optical disk such as CD-R or CD-RW, or a DVD-R (DVD recordable), DVD-RW (DVD rewritable), or the like. The optical disk recording apparatus can be a two-substrate bonded optical disk such as a DVD-based optical disk.

  Embodiments of the present invention will be described below. An embodiment of an optical disk used in the label surface image forming method of the present invention is shown in a partial sectional view in FIG. 2 (thicknesses of the respective layers are different from actual ones, and illustration of guide grooves is omitted). This is designed so that an image can be formed on the label surface of a CD-R disc. This optical disk 10 is formed by sequentially forming a dye layer (recording layer) 14, a reflective layer 16, a visible light characteristic changing layer 18, and a protective layer 20 on one side of a transparent substrate 12 such as polycarbonate, and is configured integrally as a whole. It is. It is the same as a normal CD-R disc except that there is a visible light characteristic changing layer 18. From the label surface 22 side, the visible light characteristic changing layer 18 can be desired through the transparent protective layer 20. The visible light characteristic changing layer 18 is irradiated with laser light having a predetermined power or more from the label surface 22 side, and the visible light characteristics {color (hue, brightness, saturation) from the label surface 22 side of the irradiated portion. , Spectrum, reflectance, transmittance, light scattering, etc., for example, the color of the photosensitive material or heat sensitive material changes {for example, white to color (black, etc.), transparent to color (black, etc.) Etc.} can be constituted by a layer of material (color change layer by photosensitive layer, heat-sensitive layer, etc.). When the visible light characteristic changing layer 18 is formed of a photosensitive layer, for example, with respect to laser light having a wavelength of 780 nm incident from the label surface 22 side, the laser light power is less than 1 mW, and the laser light is not exposed to 1 mW or more. Photosensitive materials that change color when exposed to light can be used. When the visible light characteristic changing layer 18 is formed of a heat-sensitive layer, for example, a heat-sensitive material that does not heat at less than 100 degrees Celsius but changes heat and discolors at 100 degrees Celsius or more can be used. When recording or reproducing data on the optical disc 10, laser light is incident from the substrate 12 side and is almost blocked by the reflective layer 16, so that the visible light characteristic changing layer 18 does not change in visible light characteristics. Further, as shown in FIG. 3, the visible light characteristic changing layer 18 has two-layer structures 18-1 and 18-2, and these two layers 18-1 and 18-2 are fused or mixed by laser light irradiation to be visible. It can also be configured such that the optical characteristics change.

As shown in FIG. 4, an intermediate layer 24 can be provided between the reflective layer 16 and the visible light characteristic changing layer 18. The intermediate layer 24 can be made of, for example, a material that improves adhesion between the reflective layer 16 and the visible light characteristic change layer 18, heat insulation, and the like. For the purpose of improving the adhesion, the intermediate layer 24 is made of a material having good adhesion to both the reflective layer 16 and the visible light characteristic changing layer 18. If the intermediate layer 24 is made of a heat-insulating material, heat during data recording and heat during image formation on the label surface are suppressed from being conducted to opposite sides, so that the heat during data recording is visible. It is possible to suppress the influence exerted on the optical characteristic changing layer and the influence exerted on the recording layer by the heat at the time of image formation on the label surface. Further, when the reflective layer 16 and the visible light characteristic changing layer 18 are in direct contact with each other, heat at the time of image formation on the label surface spreads in the surface direction through the reflective layer 16 (often made of metal) and is visible. Although there is a risk that the change efficiency of the visible light characteristic of the light characteristic change layer 18 is lowered or an image is blurred, if the intermediate layer 24 is made of a heat insulating material, the heat at the time of image formation on the label surface Is suppressed from spreading in the surface direction through the reflective layer 16, and the reduction in the efficiency of changing the visible light characteristics and the bleeding of the image can be prevented. By forming the intermediate layer 24 with a light scattering layer having translucent light scattering characteristics, it is possible to make the formed image easy to see.
As a technique for improving the adhesion between the reflective layer 16 and the visible light characteristic changing layer 18, instead of providing the intermediate layer, the visible light characteristic changing layer 18 has a large number of fine dots (for example, as shown in FIG. One point can be formed in a circular shape with a diameter of about several tens of μm or a non-circular shape having the same size (for example, using a technique such as film transfer). Further, in place of a large number of fine dots, a hole having a large number of fine holes 26 can be formed as shown in FIG. The reflective layer 16 and the protective layer 20 are directly bonded to each other outside the point when formed in the dot shape of FIG. 5 and inside the hole when formed in the hole shape of FIG. Can be improved. Further, even if the visible light characteristic changing layer 18 is opaque, the reflective layer 16 is partially formed from the label surface 22 side through the part where the visible light characteristic changing layer 18 is not provided and the reflective layer 16 and the protective layer 20 are directly joined. Therefore, it is possible to easily focus on the reflective layer 16 when forming an image on the label surface 22. In addition to dot-like and perforated shapes, concentric circles or straight stripes can be used.

Another embodiment of the optical disk used in the label surface image forming method of the present invention is shown in a partial sectional view in FIG. 7 (thicknesses of the respective layers are different from actual ones, and illustration of guide grooves is omitted). This is designed so that an image can be formed on the label surface of a CD-RW disc. In this optical disk 28, a dielectric layer 32, a recording layer 34, a dielectric layer 36, a reflective layer 38, a visible light characteristic changing layer 40, and a protective layer 42 are sequentially formed on one surface of a transparent substrate 30 such as polycarbonate, It is constructed integrally. Except for the presence of the visible light characteristic changing layer 40, it is the same as a normal CD-RW disc. From the label surface 44 side, the visible light characteristic changing layer 40 can be desired through the transparent protective layer 42. The visible light characteristic changing layer 40 can be configured in the same manner as the visible light characteristic changing layer 18 of the embodiment of FIG. Further, as in FIG. 4, an intermediate layer that enhances adhesion can be disposed between the reflective layer 38 and the protective layer 42. Further, the visible light characteristic changing layer 40 is formed into a large number of fine dots as in FIG. 5, or is formed into a perforated shape having a large number of fine holes as in FIG. 6, or concentric circles or straight stripes. It can be formed into a shape or the like.
FIG. 8 is a partial sectional view showing another embodiment of the optical disk used in the label surface image forming method of the present invention (thicknesses of the respective layers are different from actual ones, and illustration of guide grooves is omitted). This is a CD-RW disc 28 of FIG. 7 in which a separation layer 35, a second reflection layer 37, and an intermediate layer 39 are stacked between the reflection layer 38 and the visible light characteristic changing layer 40. The second reflective layer 37 can be composed of a metal layer, a dielectric reflective layer, or the like. According to this, the separation layers 35 and 38 are provided independently for image formation and data recording on the label surface, and are composed of a resin or the like interposed between the reflection layers 37 and 38. Functions as a buffer layer for heat conduction, so that it is possible to more reliably suppress the influence of heat at the time of data recording on the visible light characteristic change layer and the influence of the heat at the time of image formation on the label surface on the recording layer. The intermediate layer 39 is made of, for example, a material that improves the adhesion between the reflective layer 37 and the visible light characteristic changing layer 40 (a material having good adhesion to both the reflective layer 37 and the visible light characteristic changing layer 40). can do. Further, if the intermediate layer 39 is made of a heat insulating material, the heat at the time of image formation on the label surface is suppressed from spreading in the surface direction through the reflective layer 37, which reduces the change efficiency of visible light characteristics and blurs the image. Can be prevented. Further, by forming the intermediate layer 39 with a light scattering layer having a translucent light scattering characteristic, it is possible to make the formed image easy to see.
Another embodiment of the optical disk used in the label surface image forming method of the present invention is shown in a partial sectional view in FIG. 9 (thicknesses of the respective layers are different from actual ones, and illustration of guide grooves is omitted). In this method, an image can be formed on the label surface of a single-sided single-layer recording DVD-RW disc. In this optical disk 41, a dielectric layer 45, a recording layer 47, a dielectric layer 49, and a reflective layer 51 are sequentially formed on one surface of a transparent first substrate 43 made of polycarbonate or the like having a thickness of 0.6 mm. A 0.6 mm-thick second substrate 55 (usually a transparent substrate) made of polycarbonate or the like is bonded to the substrate by a bonding adhesive layer 53. On the surface of the second substrate 55, a second reflective layer 57, an intermediate layer 59, a visible light characteristic changing layer 61, and a protective layer 63 are sequentially laminated. The surface on the protective layer 63 side constitutes the label surface 65. Data recording is performed by irradiating the recording layer 47 with laser light from the surface side of the first substrate 43. The image formation of the label surface 65 is performed by irradiating the visible light characteristic changing layer 61 with laser light from the label surface 65 side.
The second reflective layer 57 can be composed of a metal layer, a dielectric reflective layer, or the like. The intermediate layer 59 is, for example, a material that improves the adhesion between the second reflective layer 57 and the visible light characteristic changing layer 61 (a material that has good adhesion to both the reflective layer 57 and the visible light characteristic changing layer 61. ). Further, if the intermediate layer 59 is made of a heat insulating material, the heat at the time of image formation on the label surface is suppressed from spreading in the surface direction through the reflective layer 57, so that the change efficiency of visible light characteristics and the blurring of the image are suppressed. Can be prevented. Further, by forming the intermediate layer 59 with a light-scattering layer having translucent light scattering characteristics, it is possible to make the formed image easy to see.

  FIG. 10 shows a reference example of an optical disk apparatus that forms an image on the label surface of the optical disk (only the portion related to image formation on the label surface is shown). This is configured as a CD-R / RW drive (an optical disc recording apparatus capable of recording and reproducing data on CD-R discs and CD-RW discs) used by being connected to a host computer 46 such as a personal computer. is there. In the CD-R / RW drive 48, the optical disk 50 (the CD-R disk 10 in FIGS. 2 to 6, the CD-RW disk 28 in FIG. 7, etc.) is reversed (with the label surface 52 facing downward). It is placed on the turntable 54 and is driven to rotate by a spindle motor 56. A frequency generator 58 (FG) is directly connected to the rotation shaft of the spindle motor 56, and a pulse signal (FG pulse) is generated from the frequency generator 58 at every rotation angle obtained by dividing one rotation of the spindle motor 56 by a predetermined integer. Is done. The FG pulse is multiplied to a predetermined multiple by a multiplier 60 composed of a PLL circuit or the like, and input to a system control circuit (CPU) 62 to be used for detection of a disk circumferential position. The spindle servo circuit 64 controls the spindle motor 56 at a constant rotational speed at the rotational speed instructed from the system control circuit 62 based on the FG pulse when forming the image on the label surface.

  Below the optical disk 50, an optical pickup 66 for recording data, reproducing data, and forming an image on a label surface is disposed. The optical pickup 66 is supported by a feed screw 68 so as to be movable in the radial direction of the optical disc 50. The optical pickup 66 is transported in the radial direction of the optical disk 50 by driving the feed motor 72 via the motor driver 70 and rotating the feed screw 68 in accordance with a command from the system control circuit 62. The position of the optical pickup 66 in the radial direction of the optical disk is detected by a feed position detector 74 such as a linear scale. The focus servo circuit 76 performs focus control by driving the focus actuator of the optical pickup 66 based on the focus error signal in response to a command from the system control circuit 62. When forming an image on the label surface, the focus servo circuit 76 is turned on. When recording or reproducing data, the tracking servo circuit 78 performs tracking control by driving the tracking actuator of the optical pickup 66 based on the tracking error signal according to a command from the system control circuit 62. When forming an image on the label surface, the tracking servo circuit 78 is turned off. The vibration signal generation circuit 80 generates a predetermined vibration signal according to a command from the system control circuit 62 and supplies it to the tracking actuator when forming an image on the label surface. As a result, the objective lens of the optical pickup 66 vibrates in the radial direction of the optical disk 50, and the scanning interval of the laser light for each round is filled, so that a clear image is obtained.

  The laser driver 82 drives the laser diode of the optical pickup 66 in accordance with a command from the system control circuit 62, and irradiates the optical disk 50 with the laser light to perform data recording, data reproduction, and image formation on the label surface. That is, the laser diode emits a laser beam having a recording power modulated by a recording signal during data recording, emits a laser beam having a constant reproduction power during data reproduction, and forms an image when forming an image on the label surface. Laser light modulated with image data such as letters, pictures, etc. (high power that causes changes in the visible light characteristics of the visible light characteristic changing layer in the image forming part, and the visible light characteristic changing layer in the part where no image is formed) Laser light having a low power that does not cause a change in visible light characteristics) is emitted. When image formation on the label surface is performed, image data such as characters and pictures to be image-edited edited by the user is sent from the host computer 46 to the CD-R / RW drive 48. This image data is, for example, data represented by coordinates (r, θ) based on a combination of a radial position r (distance from the center of rotation) and a circumferential position θ (circumferential angle with respect to an appropriate reference position). For example, for each radial position r having a predetermined pitch Δr, the image forming section represented by an angle θ is defined.

The image forming process of the label surface of the optical disk 50 by the CD-R / RW drive 48 of FIG. 10 is performed as follows, for example.
(1) The optical disk 50 is mounted on the turntable 54 so that it is upside down from the time of data recording or reproduction.
(2) A user edits an image such as a character or a picture to be formed on the display of the host computer 46. The host computer 46 converts the edited image into image data.
(3) The user instructs the start of the image forming operation on the host computer 46.
(4) The spindle servo circuit 64 controls the spindle motor 56 by CAV (constant rotational speed) so that the pulse generated from the frequency generator 58 has a constant frequency commanded by the system control circuit 62.
(5) The optical pickup 66 is positioned at a predetermined radial reference position on the inner peripheral side of the optical disc 50.
(6) The laser power of the laser diode of the optical pickup 66 is a predetermined low output commanded by the system control circuit 62 (the visible light characteristic of the visible light characteristic changing layer does not change and the focus control is possible). The laser driver 82 drives the laser diode so that the value is 1 mW or less.
(7) The focus servo circuit 76 is turned on according to an instruction from the system control circuit 62. Thereby, the focus servo circuit 76 applies focus servo so that the laser beam 67 becomes the minimum spot on the reflection layer. The tracking servo circuit 78 remains off and no tracking servo is applied.
(8) Preparation for image formation is now complete, and image formation is started by an instruction from the system control circuit 62. That is, the system control circuit 62 inputs image data from the host computer 46, drives the feed motor 72, and positions the optical pickup 66 at the radial position where the first image forming portion is located on the inner peripheral side of the optical disk 50, and the FG pulse. The output pulse of the multiplier 60 is counted by using an appropriate timing based on (or a detection timing of a detector provided separately for detecting a circumferential reference position) as a circumferential reference position, and the circumferential position θ The laser power is detected at each image forming position in the circumferential direction indicated by the image data for the radial position at a predetermined high output (a value at which the visible light characteristic of the visible light characteristic changing layer changes, for example, a value of 1 mW or more ). As a result, the visible light characteristic of the visible light characteristic change layer changes (discoloration or the like) at the portion irradiated with the high-power laser light, and image formation is performed. When the optical disk 50 makes one rotation and returns to the reference position in the circumferential direction, the feed motor 62 is driven to move the optical pickup 66 in the outer circumferential direction by a predetermined pitch Δr, and the radial position in the circumferential direction indicated by the image data. Image formation is performed by switching the laser power to a predetermined high output at each image forming position. Thereafter, this operation is repeated, and image formation is performed by sequentially moving in the outer circumferential direction at a predetermined pitch Δr every round. FIG. 11 shows the locus of the laser beam on the label surface 52 of the optical disc 50 by this image forming operation. The laser power is switched to a high output at the portion drawn with a thick line, and image formation is performed. FIG. 12 shows changes in laser power when the image formation of FIG. 11 is performed.

  It should be noted that a radius position where there is no image forming portion is not scanned, and the next image forming portion moves to a certain radial position at a time to form an image. Further, when the pitch Δr is large, as shown in FIG. 13, even if the image should originally be formed connected in the radial direction, a gap occurs and an image is formed. If the pitch Δr is reduced, the gap can be made inconspicuous, but the number of rounds required to form an image on the entire label surface increases, and the image formation takes time. Therefore, in the CD-R / RW drive 48 of FIG. 10, the tracking actuator is driven by a vibration signal (sine wave, triangular wave, etc.) generated from the vibration signal generation circuit 80 during image formation, and the objective lens is moved in the disk radial direction. I try to vibrate. As a result, as shown in FIG. 14, the laser beam vibrates in the disk radial direction, and an image can be formed without a gap (or with a small gap) even if the pitch Δr is relatively large. The frequency of the vibration signal can be set to about several kHz, for example. The pitch Δr can be set to about 50 to 100 μm, for example.

  FIG. 15A shows an actual image formation example of the label surface 52 by the CD-R / RW drive 48 of FIG. FIG. 4B shows a partially enlarged view of the locus of the laser beam when this is formed. When scanning the position of the radius r1, the laser power is output at a high angle in the interval of θ1 to θ2. It shows the state to be. FIGS. 16A, 16B, and 16C show other examples of image formation on the label surface 52 by the CD-R / RW drive 48, respectively. Arbitrary character information such as a disc title, song name, artist name, picture, etc. can be formed as an image.

  FIG. 1 shows an embodiment of an optical disk apparatus according to the present invention (only the part related to image formation on the label surface is shown). In the CD-R / RW drive 84, the optical disk 50 (the CD-R disk 10 in FIGS. 2 to 6, the CD-RW disk 28 in FIG. 7, etc.) is reversed (with the label surface 52 facing downward). It is placed on the turntable 86. When image formation is performed, the spindle motor 88 is not driven. Below the optical disc 50, an optical pickup 90 for recording and reproducing data is disposed. The optical pickup 90 is supported by a feed screw 92 so as to be movable in the radial direction of the optical disc 50. The optical pickup 90 is transported in the radial direction of the optical disk 50 by driving the feed motor 94 via the motor driver 96 and rotating the feed screw 92 in accordance with a command from the system control circuit 62. The position of the optical pickup 90 in the radial direction of the optical disk is detected by a feed position detector 98 such as a linear scale.

  The disk radial feed mechanism having the feed screw 92 and the feed motor 94 is entirely tangential to the track (in the feed direction in the disk radial direction) by a feed screw 101 that is orthogonal to the feed screw 92 and parallel to the surface of the disk 50. It is supported so as to be movable in an orthogonal direction. In response to a command from the system control circuit 105, the feed motor 103 is driven via the motor driver 107 to rotate the feed screw 101, whereby the optical pickup 90 is transferred in the track tangential direction. The position of the optical pickup 90 in the track tangent direction is detected by a feed position detector 109 such as a linear scale.

  An arrangement example of the feed mechanism is shown in FIG. 17 (the feed motor and the feed screw are not shown). A slide bar 111 is fixedly disposed on the mechanical base of the CD-R / RW drive 84 in parallel with the surface of the optical disc 50. An optical pickup unit 113 is slidably supported on the slide bar 111. The optical pickup unit 113 is transferred along the slide bar 111 by the feed motor 103 and the feed screw 101 (FIG. 1). A slide bar 115 is fixedly disposed in the optical pickup unit 113 so as to be parallel to the surface of the optical disc 50 and perpendicular to the slide bar 111. An optical pickup 90 is slidably supported on the slide bar 115. The optical pickup 90 is transferred along the slide bar 115 by a feed motor 94 and a feed screw 92 (FIG. 1). During image formation, the bi-directional feed mechanism is driven. When recording or reproducing data, only the track radial feed mechanism is driven, and the track tangential feed mechanism is in its neutral position (the objective lens 90a of the optical pickup 90 is moved in the disk radial direction by driving the track radial feed mechanism). Stopped at the transfer position).

  The track tangential feed mechanism may be configured to transport the spindle motor 88 instead of transporting the optical pickup 90. In that case, in FIG. 1, instead of the feed screw 101 and the feed motor 103 for transferring the optical pickup 90 in the track tangential direction, a feed screw 117 and a feed motor 119 for transferring the spindle motor 88 in the same direction are provided. An arrangement example of the feed mechanism in that case is shown in FIG. 18 (a feed motor and a feed screw are not shown). On the mechanical base of the CD-R / RW drive 84, a slide bar 121 is fixedly disposed in parallel to the surface of the optical disc 50. A spindle motor 88 is slidably supported on the slide bar 121. The spindle motor 88 is transferred along the slide bar 121 by a feed motor 119 and a feed screw 117 (FIG. 1). A slide bar 123 is fixedly disposed on the mechanical base of the CD-R / RW drive 84. An optical pickup 90 is slidably supported on the slide bar 123. The optical pickup 90 is transferred along the slide bar 123 by a feed motor 94 and a feed screw 92 (FIG. 1). During image formation, the bi-directional feed mechanism is driven. When recording or reproducing data, only the track radial feed mechanism is driven, and the track tangential feed mechanism is in its neutral position (the objective lens 90a of the optical pickup 90 is moved in the disk radial direction by driving the track radial feed mechanism). Stopped at the transfer position).

  In FIG. 1, a focus servo circuit 125 performs focus control by driving a focus actuator of the optical pickup 90 based on a focus error signal according to a command from the system control circuit 105. When forming an image on the label surface, the focus servo circuit 125 is turned on. When recording or reproducing data, the tracking servo circuit 127 performs tracking control by driving the tracking actuator of the optical pickup 90 based on the tracking error signal according to a command from the system control circuit 105. When forming an image on the label surface, the tracking servo circuit 127 is turned off. The vibration signal generation circuit 129 generates a predetermined vibration signal according to a command from the system control circuit 105 and supplies it to the tracking actuator when forming an image on the label surface. As a result, the objective lens of the optical pickup 90 vibrates in the radial direction of the optical disc, and the scanning interval of the laser light for each round is filled, so that a clear image is obtained.

  The laser driver 131 drives the laser diode of the optical pickup 90 in accordance with a command from the system control circuit 105 and irradiates the optical disk 50 with the laser light to perform data recording, data reproduction, and label surface image formation. That is, the laser diode emits a laser beam having a recording power modulated by a recording signal when data is recorded by driving the laser driver 131, and emits a constant laser beam with a reproducing power when reproducing data. During formation, laser light modulated with image data such as characters and pictures to be imaged (high power that causes a change in the visible light characteristics of the visible light characteristic changing layer in the image forming part, and the part where no image is formed The laser light having a low power that does not cause a change in the visible light characteristics of the visible light characteristic changing layer is emitted. When image formation on the label surface is performed, image data such as characters and pictures to be image-edited by the user is sent from the host computer 133 to the CD-R / RW drive 84. This image data includes, for example, a radial position r of the optical disk {a distance from an appropriate reference position (for example, the rotation center) in the disk radial direction} and a track tangential position t (a distance from an appropriate reference position in the track tangential direction). It is composed of dot matrix data represented by coordinates (r, t) by combination (for example, data defining an image forming section in the track tangential direction represented by t for each radial position r of a predetermined pitch Δr).

The image forming process of the label surface of the optical disc 50 by the CD-R / RW drive 84 of FIG. 1 is performed as follows, for example.
(1) The optical disk 50 is mounted on the turntable 86 so as to be upside down when recording or reproducing data.
(2) A user edits an image such as a character or a picture to be formed on the display of the host computer 133. The host computer 133 converts the edited image into image data.
(3) The user instructs the start of the image forming operation on the host computer 133.
(4) The spindle motor 88 is stopped during the image forming operation in response to an instruction from the system control circuit 105.
(5) Position the optical pickup 90 at a predetermined reference position.
(6) The laser power of the laser diode of the optical pickup 90 is a predetermined low output commanded by the system control circuit 105 (the visible light characteristic of the visible light characteristic changing layer does not change and the focus control is possible, for example, The laser driver 131 drives the laser diode so that the value is 1 mW or less.
(7) The focus servo circuit 125 is turned on according to an instruction from the system control circuit 105. Accordingly, the focus servo circuit 125 applies focus servo so that the laser beam becomes the minimum spot 91 on the reflective layer. The tracking servo circuit 127 remains off and no tracking servo is applied.
(8) Preparation for image formation is now complete, and image formation is started in response to an instruction from the system control circuit 105. That is, the system control circuit 105 inputs image data from the host computer 133, drives the feed motor 94, and positions the optical pickup 90 at the disk radial direction position where the first image forming portion is located on the inner circumference side of the optical disk 50, The laser beam is moved in the track tangential direction by driving the motor 103 (or 119) at the disk radial position, and the laser power is set over the image formation section in the track tangential direction indicated by the image data for the disk radial position. To a high output (a value at which the visible light characteristic of the visible light characteristic changing layer changes, for example, a value of 1 mW or more). As a result, the visible light characteristic of the visible light characteristic change layer changes (discoloration or the like) at the portion irradiated with the high-power laser light, and image formation is performed. Subsequently, the feed motor 94 is driven to move the optical pickup 90 in the outer circumferential direction by a predetermined pitch Δr, and while moving in the track tangential direction at that position, the track tangential direction indicated by the image data with respect to the disk radial direction position. The image is formed by switching the laser power to a predetermined high output over the image forming section. Thereafter, this operation is repeated, and image formation is performed by sequentially moving in the outer peripheral direction at a predetermined pitch Δr. FIG. 19 shows the locus of the laser beam on the label surface 52 of the optical disc 50 and the resulting image by this image forming operation. Since the laser beam moves while vibrating by the vibration signal, an image having no gap (or a small gap) can be obtained.

  In the above-described embodiment, the visible light characteristic changing layer is disposed between the reflective layer and the protective layer. However, the visible light characteristic changing layer is provided at any position (for example, on the protective layer) that is visible from the label surface side of the optical disc. Can be arranged. Further, in the above-described embodiment, the case where image formation is performed on an optical disc integrally formed with the visible light characteristic change layer has been described. However, image formation by the label surface image forming method or the optical disc apparatus of the present invention is not limited to this. is not. That is, an image can be formed by applying the label surface image forming method or the optical disk device of the present invention to an optical disk in which a label having a visible light characteristic changing layer is attached to the label surface. In the above embodiment, the image is formed on the label surface while applying the focus servo. However, if the image resolution is not required, the image can be formed without applying the focus servo. In this case, since it is not necessary to obtain the reflected light necessary for the focus servo, the visible light characteristic changing layer can be formed in an opaque state in which the reflective layer cannot be seen through. In the embodiment, the image is formed by modulating the power of the laser beam according to the image data. However, the visible light characteristic can be obtained by modulating the image according to the image data with parameters of the laser beam other than the power. If there is a parameter that can change the visible light characteristic of the change layer, the parameter can be modulated to form an image. In addition, the visible light characteristic change mode of the visible light characteristic change layer is not limited to the above-described one, and may be any change that can be visually recognized. In the above embodiment, the images are sequentially formed from the inner periphery side to the outer periphery side of the disc. However, the present invention is not limited to this. Image formation can be performed in order. In the above embodiment, the case of forming an image on a CD-R disc or a CD-RW disc has been described. However, the present invention can also be applied to the case of forming an image on another optical disc. In the above embodiment, the case where the present invention is applied to an optical disk apparatus connected to a host computer has been described. However, the present invention is not limited to this, and the present invention is applied to an optical disk apparatus used alone, such as a CD recorder. Can also be applied.

1 is a system configuration block diagram showing an embodiment of an optical disk device of the present invention. It is a fragmentary sectional view which shows embodiment of the optical disk used for the label surface image forming method of this invention. It is a fragmentary sectional view which shows the modification of the optical disk of FIG. It is a fragmentary sectional view which shows the modification of the optical disk of FIG. It is a fragmentary sectional view which shows the modification of the optical disk of FIG. It is a fragmentary sectional view which shows the modification of the optical disk of FIG. It is a fragmentary sectional view which shows other embodiment of the optical disk used for the label surface image forming method of this invention. It is a fragmentary sectional view which shows other embodiment of the optical disk used for the label surface image forming method of this invention. It is a fragmentary sectional view which shows other embodiment of the optical disk used for the label surface image forming method of this invention. 1 is a system configuration block diagram showing a reference example of an optical disc apparatus that forms an image on a label surface of an optical disc. FIG. 11 is a plan view showing a locus of laser light on the label surface by an image forming operation on the label surface using the CD-R / RW drive of FIG. 10. FIG. 12 is a diagram showing a change in laser power when the image formation of FIG. 11 is performed. It is a top view which shows the locus | trajectory of the laser beam on a label surface when image formation is performed without vibrating a laser beam in the disk radial direction. It is a top view which shows the locus | trajectory of the laser beam on a label surface when image formation is performed by vibrating a laser beam in the disk radial direction. It is a top view which shows the image formation example of the label surface by the CD-R / RW drive of FIG. FIG. 11 is a plan view showing another example of image formation on the label surface by the CD-R / RW drive of FIG. 10. It is the top view and front view which show the example of arrangement | positioning of the CD-R / RW drive feed mechanism of FIG. It is the top view and front view which show the example of arrangement | positioning of the CD-R / RW drive feed mechanism of FIG. FIG. 2 is a plan view showing an example of image formation on a label surface by the CD-R / RW drive of FIG. 1.

Explanation of symbols

  10, 28, 41, 50 ... optical disc, 12, 30, 43, 55 ... substrate, 14, 34, 47 ... recording layer, 16, 38, 51 ... reflective layer, 18, 40, 61 ... visible light property changing layer, 20, 42 ... protective layer, 22, 44, 52 ... label surface, 24, 39, 59 ... intermediate layer, 26 ... hole, 35 ... separation layer, 37, 57 ... second reflective layer, 48, 84 ... CD- R / RW drive (optical disk device), 54, 86 ... turntable, 56 ... spindle motor, 58 ... frequency generator, 60 ... multiplier, 62, 105 ... system control circuit (control circuit), 66, 90 ... optical pickup , 67, 91 ... laser light, 68, 72, 92, 94, 101, 103, 111, 113, 115, 117, 119, 121, 123 ... relative movement mechanism, 72, 94 ... feed motor (radial feed drive device) 74, 98 ... Feed position detector (radial position detector), 76, 125 ... Focus servo circuit, 78, 127 ... Tracking servo circuit, 80, 129 ... Vibration signal generation circuit, 82, 131 ... Laser driver (laser) Modulation circuit), 103, 119 ... feed motor (track tangential feed driving device), 109 ... feed position detector (track tangential position detection device)

Claims (4)

A visible light property changing layer in which the visible light property from the label surface side is changed by irradiation of the laser beam from the label surface side is formed at a location visible from the label surface side of the optical disc, An optical disc is set with its label surface facing the incident side of the laser beam emitted from the optical pickup, and the optical disc and the laser beam are moved relative to each other along the surface of the optical disc, in synchronization with the relative movement. The laser light is modulated in accordance with image data such as characters and pictures to be imaged and irradiated to the visible light characteristic change layer from the label surface side, and the visible light of the visible light characteristic change layer is irradiated by the irradiation. In the label surface image forming method of the optical disc for forming an image corresponding to the label surface by changing the characteristics,
A label surface image forming method for an optical disc, wherein the optical disc is stopped and the optical pickup is moved in a radial direction of the optical disc and a track tangential direction perpendicular to the radial direction of the optical disc to form the image. A relative movement mechanism for relatively moving the optical disk set with the label surface facing the laser light incident side on the turntable and the laser light emitted from the optical pickup along the surface of the optical disk;
A laser modulation circuit for modulating laser light emitted from the optical pickup;
Comprising the relative movement mechanism and a control circuit of the laser modulation circuit;
The control circuit controls the relative movement mechanism to move the optical disk and the laser beam relative to each other, and the laser modulation circuit is used to form an image on the label surface of the optical disk and the relative movement. The laser beam emitted from the optical pickup is modulated in accordance with the image data, the laser beam emitted from the optical pickup is modulated by the image data, and the corresponding image is formed at a position visible from the label surface side of the optical disc. In an optical disc apparatus that performs control to form an image on a visible light characteristic changing layer whose visible light characteristics change depending on
A radial feed driving device in which the relative movement mechanism moves the optical pickup in the radial direction of the optical disc, and a track tangential feed in which the optical pickup moves in the track tangential direction of the optical disc perpendicular to the radial movement direction. An optical disc apparatus comprising a drive device, wherein the control circuit controls both the drive devices in a state where the turntable is stationary to control relative movement between the optical disc and the laser beam.   A radial position detecting device for detecting an optical disk radial position of the optical pickup; and a track tangential position detecting device for detecting an optical disk track tangential position orthogonal to a moving direction of the optical pickup in the optical disk radial direction. The control circuit modulates the laser light emitted from the optical pickup in accordance with the detection position of both the position detection devices and the image data such as characters and pictures to be formed on the label surface of the optical disc. The optical disc apparatus according to claim 2, wherein:   When recording or reproducing data on the recording layer of the optical disc, only the radial feed driving device is driven, and the track tangential feed driving device is in its neutral position (the objective of the optical pickup is driven by the radial feed driving device). 4. The optical disk device according to claim 2, wherein the lens is stopped at a position where the lens is moved in the disk radial direction.

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