JP2011210324A - Method for manufacturing recording medium and recording medium manufactured by the method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enhance productivity in a method for manufacturing a recording medium and the recording medium manufactured by the method.SOLUTION: The method for manufacturing a recording medium includes a first step of disposing the plate-shaped recording medium 14 having grooves 18 at a prescribed pitch on one surface side in a prescribed position, a second step of making a first parallel beam incident from the one surface side of the recording medium 14 and making a second parallel beam incident from the other surface side of the recording medium 14, a third step of covering the grooves 18 of the recording medium 14 with a transparent resin 21 and disposing the recording medium 14 in a prescribed position and a fourth step of making the first parallel beam incident from the one surface side of the recording medium 14 and making the second parallel beam incident from the other surface side of the recording medium 14.

Description

  The present invention relates to a method for manufacturing a recording medium in which a plurality of hologram layers are provided in a multilayer state in the thickness direction, and a recording medium manufactured thereby.

  In recent years, in order to increase the recording capacity, a multi-layered recording medium has been proposed as shown below (Patent Document 1).

  That is, in the following (Patent Document 1), as shown in FIG. 11C, the hologram layer 2 is provided in a multilayer state in the thickness direction in the disc-shaped recording medium 1, so that the recording capacity is Is extremely large.

  The feature of the conventional example shown in this (Patent Document 1) is that a plurality of hologram layers 2 in which micro-holograms 3 are arranged in a spiral shape or concentric shape are provided in the recording medium 1. It is only necessary to irradiate light from one side of the recording medium 1 toward the micro-hologram 3 during recording on the medium 1 or during reproduction.

  That is, at the time of recording, light is irradiated from one side of the recording medium 1 to the micro-hologram 3 of the recording portion, causing optical alteration, and the portion where the micro-hologram 3 disappears, and the light is not irradiated. Digital recording can be performed by forming a portion where 3 remains.

  Also, during reproduction, digital reproduction can be performed by irradiating light from one side of the recording medium 1 to the disappearing portion of the micro-hologram 3 and the remaining portion of the micro-hologram 3 and reading the reflected light therefrom. it can.

US Pat. No. 7,388,695

  In the above conventional example, the recording medium 1 is manufactured by the following procedure.

  First, as shown in FIG. 8, the reference light 5 is incident on the master disk 4 from one outer surface side (for example, from the upper surface), and from the other outer surface side of the master disk 4 (for example, the lower surface). From the above, recording light 6 is incident on the master disk 4 to form a micro-hologram 7 in the master disk 4, thereby completing the master disk 4.

  Next, as shown in FIG. 9, the conjugated master disk 8 is superposed on the master disk 4, and in this state, the parallel light 9 is incident from the conjugated master disk 8 side as shown in FIG.

  Then, as shown in FIG. 10B, the reflected light 10 from the micro-hologram 7 in the master disk 4 is generated, and this reflected light 10 and the parallel light 9 interfere in the conjugate master disk 8, thereby A hologram 11 is formed in the master disk 8. That is, this completes the conjugate master disk 8.

  Thereafter, as shown in FIG. 11A, the recording medium 1 still in the blank disk state is superposed on the conjugate master disk 8, and parallel light 12 is incident from the recording medium 1 side.

  Then, as shown in FIG. 11 (b), reflected light 13 from the hologram 11 is generated, and this reflected light 13 and the parallel light 12 interfere with each other in the recording medium 1 in a blank disk state. A micro-hologram 3 is formed in 1. That is, the recording medium 1 is completed.

  As apparent from the above description, the conventional method for manufacturing the recording medium 1 requires the master disk 4 and the conjugate master disk 8 to be formed in advance, which is very time-consuming and low in productivity. Met.

  Accordingly, an object of the present invention is to improve the productivity of a recording medium.

  In order to achieve this object, according to the present invention, a plate-like recording medium having grooves at a predetermined pitch is arranged at a predetermined position on one side, and the recording medium is inserted into the recording medium from one side of the recording medium. The first parallel light is incident and the second parallel light is incident on the recording medium from the other surface side of the recording medium, and then the groove of the recording medium is covered with a transparent resin. The first parallel light is incident on the recording medium from one side of the recording medium, and the second parallel light is incident on the recording medium from the other side of the recording medium. The purpose of the period is achieved.

  As described above, the present invention includes the first step of disposing a plate-like recording medium having grooves at a predetermined pitch on one side at a predetermined position, and the first side of the recording medium into the recording medium. A second step of causing one parallel light to enter and second parallel light to enter the recording medium from the other surface side of the recording medium, and then forming the groove of the recording medium with a transparent resin. And a third step of arranging the recording medium at a predetermined position, and then entering the first parallel light into the recording medium from one side of the recording medium and Since the fourth step of allowing the second parallel light to enter the recording medium from the surface side is provided, the productivity is extremely high.

  That is, in the present invention, a plurality of hologram layers can be formed in the recording medium by the Talbot effect in the second and fourth steps, respectively. Since a plurality of hologram layers can be formed directly in the recording medium without forming a disc in advance, the productivity is extremely high.

  Further, in the second step and the fourth step, the hologram layer can be formed at different portions in the recording medium, so that the recording density can be increased.

1 is a perspective view showing a recording medium according to a first embodiment of the present invention. (A) Sectional drawing which shows the manufacturing method of the recording medium, (b) Sectional drawing Sectional drawing which shows the manufacturing method of the recording medium Sectional drawing which shows the manufacturing method of the recording medium Sectional view of a recording medium manufactured by the manufacturing method Sectional drawing of the recording medium manufactured by the manufacturing method of the recording medium concerning Embodiment 2 of this invention Sectional drawing of the recording medium manufactured by the manufacturing method of the recording medium concerning Embodiment 3 of this invention Diagram showing conventional manufacturing method Diagram showing the manufacturing method Diagram showing the manufacturing method Diagram showing the manufacturing method

  Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

(Embodiment 1)
In FIG. 1, reference numeral 14 denotes a recording medium manufactured by the manufacturing method according to the first embodiment of the present invention. A through hole 15 is formed in the central portion, and an intermittent spiral shape is formed inside. Alternatively, the continuous spiral hologram layer 16 is formed in a multilayer state.

  Hereinafter, a method for manufacturing the recording medium 14 will be described.

  First, as shown in FIG. 2A, a groove 18 is formed on one surface (for example, the lower surface) of the recording medium 14 with a mold 17 as shown in FIG.

  The grooves 18 have a spiral shape similar to the hologram layer 16, and the pitch between the inner and outer circumferences is p, as is the pitch between the inner and outer circumferences of the spiral hologram layer 16.

  In the present embodiment, the hologram layer 16 has a shape in which micro-holograms are continuously formed in a spiral shape.

  Further, when the optical refractive index of the synthetic resin forming the recording medium 14 is (n1), the depth d of the groove 18 is d≈λ / 4 (n1-1).

  In this state, as a matter of course, the hologram layer 16 is not yet formed in the recording medium 14 and is a blank disc state.

  Next, as shown in FIG. 3, the recording medium 14 is horizontally arranged at a predetermined position, and the first parallel light (recording light) enters the recording medium 14 from one surface side (lower surface side) of the recording medium 14. 19 is incident, and second parallel light (wavelength is 405 nm) 20 is incident as reference light into the recording medium 14 from the other surface side (upper surface side) of the recording medium 14.

  At this time, paying attention to the groove 18 side of the recording medium 14, the optical refractive index of the groove 18 is (1), as is the case with air, because air is present inside the groove.

  However, the recording medium 14 is present in a convex state in a portion adjacent to the groove 18, and the optical refractive index of the convex portion is higher than the optical refractive index (1) of air as described above (n1). ).

  As a result, a phase-type Talbot effect generation grating is formed on the groove 18 side of the recording medium 14, whereby the diffraction phenomenon of the first parallel light (recording light) 19 (in order to facilitate understanding, the 0th order As a result of the interference between the diffracted light and the second parallel light (reference light) 20, the hologram layer 16a is formed.

  The hologram layer 16a is simultaneously formed in a plurality of layers for every Talbot distance T / 2 in the recording medium 14 as shown in FIG. 5 by the Talbot effect.

  At this time, the odd-numbered hologram layer 16a counted from the groove 18 side faces the groove 18, and the even-numbered hologram layer 16a counted from the groove 18 side faces the portion between the grooves 18. .

  Next, as shown in FIG. 4, the inside of the groove 18 is covered with a transparent resin 21, and then, from one surface side (lower surface side) of the recording medium 14 into the recording medium 14, the first parallel light ( 19 is incident, and second parallel light (wavelength is 405 nm) 20 is incident as reference light into the recording medium 14 from the other surface side (upper surface side) of the recording medium 14.

  The optical refractive index (n2) of the transparent resin 21 is set larger than the optical refractive index (n1) of the synthetic resin forming the recording medium 14.

  As a result, the hologram layer 16b is simultaneously formed between the hologram layers 16a of the respective layers as shown in FIGS.

  At this time, if the relationship between the light refractive index (n1) of the recording medium 14 and the light refractive index (n2) of the transparent resin 21 is n1-n2 = n1-1 (light refractive index of air), FIG. As described above, the hologram layer 16a and the hologram layer 16b can be formed on the same surface.

  Further, on this same plane, the distance between the adjacent hologram layer 16a and the hologram layer 16b is ½ of the pitch p between the adjacent grooves 18, so that the recording density can be improved.

  In this state, a spiral hologram layer 16 as shown in FIG. 1 is formed by the hologram layer 16a and the hologram layer 16b existing on the same plane.

  Specifically, the hologram layer 16a and the hologram layer 16b are in a state in which a part of the spiral hologram layer 16 is divided and formed.

  Further, whether the hologram layer 16 has a continuous spiral shape, an intermittent spiral shape, or a concentric shape can be freely formed by forming the grooves 18.

  Further, the distance between the lower hologram layer 16 formed in this way is 1/2 of the Talbot distance T as described above.

  That is, the distance between the upper and lower hologram layers 16a facing the groove 18 shown in FIG. 5 is the Talbot distance T, and the hologram layer 16b exists between the lower hologram layers 16a. The interval between the lower hologram layers 16 is ½ of the Talbot distance T.

  The Talbot distance T is obtained by multiplying the square of the pitch p of the groove 18 by n1 / λ.

(Embodiment 2)
FIG. 6 shows a recording medium manufactured by the manufacturing method according to the second embodiment of the present invention. In this example, the adjacent hologram layer 16a and hologram layer 16b are arranged in the vertical direction in the recording medium. There is a difference.

  Specifically, the hologram layer 16b is formed below the hologram layer 16a.

  In order to do this, the relationship between the light refractive index (n1) of the recording medium 14 and the light refractive index (n2) of the transparent resin 21 is expressed as n2-n1> n1-1 (air light refractive index). Then, the hologram layer 16b can be formed below the hologram layer 16a.

(Embodiment 3)
FIG. 7 shows a recording medium manufactured by the manufacturing method according to the third embodiment of the present invention. Also in this example, the adjacent hologram layer 16a and hologram layer 16b are arranged in the vertical direction in the recording medium 14. There is a difference.

  Specifically, the hologram layer 16a is formed below the hologram layer 16b.

  In order to do this, the relationship between the light refractive index (n1) of the recording medium 14 and the light refractive index (n2) of the transparent resin 21 is expressed as n2-n1 <n1-1 (light refractive index of air). Then, the hologram layer 16a can be formed below the hologram layer 16b.

  Since the hologram layer 16 is formed concentrically in the recording medium 14 formed as described above, information recording and information reading on the recording medium 14 are performed as follows.

  That is, the recording medium 14 is mounted on a recording / reproducing apparatus (not shown), and information recording and subsequent reproduction are performed.

  Specifically, at the time of recording, the recording / reproducing light (wavelength 405 nm) is converged on the hologram layer 16 portion corresponding to, for example, “digital signal 1” with a recording / reproducing lens (not shown). Disappear part of micro-hologram. Conversely, the micro-hologram portion corresponding to “digital signal 0” is not irradiated with light, thereby leaving the micro-hologram.

  Thereafter, when reproducing the recorded information, the hologram layer 16 is irradiated with recording / reproducing light having a wavelength of 405 nm through a lens (not shown), and the digital signal is reproduced from the reflected light therefrom.

  In other words, there is no reflected light of the recording / reproducing light from the part where the micro-hologram has disappeared, and there is a reflected light of the recording / reproducing light from the part where the micro-hologram is left. Is done.

  At the time of reproduction, the recording medium 14 is continuously rotated at a high speed, and the irradiation time of the recording / reproducing light is extremely short, and the irradiation power is very low as compared with the time of recording. The remaining micro-hologram does not deteriorate.

  As described above, the present invention includes the first step of disposing a plate-like recording medium having grooves at a predetermined pitch on one side at a predetermined position, and the first side of the recording medium into the recording medium. A second step of causing one parallel light to enter and second parallel light to enter the recording medium from the other surface side of the recording medium, and then forming the groove of the recording medium with a transparent resin. And a third step of arranging the recording medium at a predetermined position, and then entering the first parallel light into the recording medium from one side of the recording medium and Since the fourth step of allowing the second parallel light to enter the recording medium from the surface side is provided, the productivity is extremely high.

  That is, in the present invention, a plurality of hologram layers can be formed in the recording medium by the Talbot effect in the second and fourth steps, respectively. Since a plurality of hologram layers can be formed directly in the recording medium without forming a disc in advance, the productivity is extremely high.

  Further, in the second step and the fourth step, the hologram layer can be formed at different portions in the recording medium, so that the recording density can be increased.

  For this reason, it is expected to be widely used as a recording medium manufacturing method and a recording medium manufactured thereby.

14 Recording medium 15 Through-hole 16 Hologram layer 16a, 16b Hologram layer 17 Mold 18 Groove 19 First parallel light 20 Second parallel light 21 Transparent resin

Claims (5)

A first step of arranging a plate-like recording medium having grooves at a predetermined pitch on one side at a predetermined position, and a first parallel light incident on the recording medium from one side of the recording medium A second step of allowing the second parallel light to enter the recording medium from the other surface side of the recording medium, and then covering the groove of the recording medium with a transparent resin. A third step of arranging at a predetermined position, and then entering the first parallel light into the recording medium from one side of the recording medium and entering the recording medium from the other side of the recording medium And a method for manufacturing a recording medium, comprising a fourth step of allowing the second parallel light to enter. The method of manufacturing a recording medium according to claim 1, wherein the groove is formed in a spiral shape on one surface side of the recording medium. The method for manufacturing a recording medium according to claim 1, wherein a plurality of grooves are formed concentrically on one surface side of the recording medium. A recording medium manufactured using the method for manufacturing a recording medium according to claim 1, wherein the recording medium has an intermittent spiral shape or a continuous spiral shape. A recording medium on which a hologram layer is formed. A recording medium manufactured using the method for manufacturing a recording medium according to claim 1, wherein a hologram layer is formed concentrically in the recording medium.

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