KR100555796B1 - Holographic master system for manufacturing a master disk and apparatus for fabricating holographic rom disk using a master disk - Google Patents

Abstract

The holographic master system according to the present invention comprises a light source for generating laser light, a light separator for reflecting a part of the laser light and transmitting another part to separate the laser light into a reference light and a signal light, and a reference light transmitted through the light separator. A first reflection mirror that reflects the first light path, a second reflection mirror that reflects the reference light reflected by the first reflection mirror at a predetermined incident angle, and a second reflection mirror connected to the second reflection mirror to drive the second reflection mirror. An actuator for changing an angle of incidence, a master disk which is rotated in connection with a power source when recording data, and an interference fringe generated by interference between signal light reflected by the optical splitter and reference light incident through the second reflection mirror, and optical A first shutter for supplying or blocking the signal light reflected from the separator to the master disk, and data being on And a control unit to control the first shutter to block the signal light from being supplied to the master disk, and to control the first shutter to supply the signal light to the master disk when data is off.

Further, the present invention arranges such a master disc and a recording disc, and then irradiates signal light to record an interference fringe on the recording disc, thereby producing a holographic ROM disc.

Description

HOLOGRAPHIC MASTER SYSTEM FOR MANUFACTURING A MASTER DISK AND APPARATUS FOR FABRICATING HOLOGRAPHIC ROM DISK USING A MASTER DISK}

1 is a structural diagram showing a holographic ROM system according to the prior art,

2 is a structural diagram of a holographic master system for producing a master disk according to the present invention,

3 is a structural diagram showing a holographic ROM disk manufacturing apparatus using a master disk according to the present invention.

<Description of the code | symbol about the principal part of drawing>

100, 200: light source 102: optical separator

104: first reflection mirror 106: second reflection mirror

108: actuator 112: first shutter

114: second shutter 116: master disk

118 motor 120 control unit

130: recording disc

The present invention relates to a holographic ROM system, and more particularly, to a holographic master system for manufacturing a master disk for manufacturing a holographic ROM disk and a holographic ROM disk manufacturing apparatus using the master disk.

Recently, a holographic disk storage system capable of storing hundreds to hundreds of Gbytes on an optical recording medium such as an optical disk for large-capacity and high-speed processing of data storage memory, among others, a holographic random access memory (HROM). Research and development on the device is actively underway.

The holographic ROM system is shown in FIG. 1 is a schematic diagram illustrating a holographic ROM system according to the related art, and includes a light source 10, a half wave plate (HWP) 12 and 22, a beam expander 14, and a beam splitter. beam splitter 16, polarizers 18, 24, reflective mirrors 20, 26, 28, conical mirror 30, optical record carrier 32, and mask 34. .

The holographic ROM system configured as described above is a three-dimensional hologram data having an interference fringe pattern generated by the interference between the optical disk, the optical recording medium 32, and the signal light and the reference light through two optical paths for recording. Record it.

Light incident from the light source 10 (for example, laser light having a wavelength of 532 nm) is provided to the beam splitter 16 via the HWP 12, the optical expander 14, and the like. The beam splitter 16 separates the laser light into signal light and reference light. The beam splitter 16 transmits the signal light as it is and reflects the reference light into two light paths.

The signal light separated by the beam splitter 16 is reflected by the reflecting mirror 20 via the polarizer 18 and the reflected signal light is modulated into a predetermined pattern by passing through a mask 34 for a mastering process. The optical disk serving as the recording medium 32 is irradiated.

The reference light separated by the beam splitter 16 is reflected by the reflection mirrors 26 and 28 via the HWP 22 and the polarizer 24 and irradiated to the conical mirror 30.

The signal light reflected by the reflection mirror 20 is incident on the optical recording medium 32. Under the optical record carrier 32, reference light spreads in parallel at the same angle to the surface of the optical record carrier 32 through the conical mirror 30 is incident. Due to the interference between the lights, the interference fringe pattern, which is three-dimensional hologram data, is recorded on the optical recording medium 32.

Then, the holographic ROM system replaces the mounted conical mirror 30 with conical mirrors having different reflection angles, and then provides the reference light and the signal light through such a path, and transmits data in an angular overlapping manner to the optical disk as the optical recording medium 32. To record.

In such a holographic ROM system, in order to store a large amount of data, the line width of the optical recording medium 32 should have a line width (0.4 μm) of a DVD capable of storing at least a large amount of data.

Thus, in order to irradiate the signal light to the optical recording medium 32 having a line width of 0.4 mu m, each pattern line width of the mask 34 used in the holographic ROM system should have a line width of at least 0.4 mu m or less.

The pattern of the mask 34 is implemented using a photomask in a semiconductor process. Since the photomask process can generally realize a line width of 0.7 μm, signal light is applied to the optical recording medium 32 having a line width of 0.4 μm. A high precision optical system is needed to reduce the signal light to be irradiated to the optical recording medium 32 between the optical recording medium 32 and the mask 34 for irradiation.

As such, when a high-precision optical system is used between the mask 34 and the optical recording medium 32, the separation distance between the mask 34 and the optical recording medium 32 increases, so that the amount of diffraction of the signal light is increased and the signal light is affected by noise. In addition, there is a problem that the structure of the system is complicated.

In order to solve this problem, there is a method of manufacturing a mask to be used in a holographic ROM system using a glass mastering process, which is a DVD disc manufacturing method.

In the glass mastering process, the polymer is coated on a substrate, and then the polymer is etched and patterned using a glass mastering device having an ODC (Optical Disk Corp) direct-read-after-write (DRAW) function. After that, a metal layer is deposited on the result of baking.

As such, when the mask is manufactured using the glass mastering process, an etching and a vacuum deposition process are required, and thus, the mask manufacturing process is complicated.

 SUMMARY OF THE INVENTION An object of the present invention is to solve such problems of the prior art, and a holographic master system and a master disc for manufacturing a master disc on which interference fringes are generated, which are generated by interference between reference light and signal light provided at different incident angles. To provide a holographic ROM disk manufacturing apparatus using.

In order to achieve the above object, the present invention, a light source for generating a laser light, an optical separator for reflecting a part of the laser light, and transmitting the other part to separate the laser light into a reference light and a signal light, and the light separator A first reflection mirror for reflecting the reference light transmitted through the first light path, a second reflection mirror for reflecting the reference light reflected by the first reflection mirror at a predetermined incident angle, and connected to the second reflection mirror; An actuator for driving a second reflecting mirror to change an incident angle of the reference light, and connected by a power source to rotate the data, and by interference between the signal light reflected by the optical splitter and the reference light incident through the second reflecting mirror The master disk on which the generated interference fringe is recorded, and the signal light reflected by the optical splitter; A first shutter for supplying or blocking a screw; and controlling the first shutter when the data is on to block the signal light from being supplied to the master disc, and when the data is off, And a control unit for controlling the signal light to be supplied to the master disk.

In addition, the present invention provides a light source for generating a first signal light in the form of a plane wave, a recording disk provided in a path of the signal light to transmit the first signal light, and an interference between the reference light and the second signal light whose incident angle is changed. An interference fringe generated by the recording medium, and including a master disk which diffracts the first signal light transmitted through the recording disk to generate reproduction light, and provides the reproduction light to the recording disk at the incident angle, An interference fringe generated by interference between the reproduction light and the signal light is recorded on the recording disc.

Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings.

2 is a structural diagram illustrating a holographic ROM master system according to the present invention, which includes a light source 100, a light separator 102, first and second reflectors 104 and 106, an actuator 108, and a first and second shutter. 112, 114, master disk 116, motor 118, and control unit 120.

The holographic ROM master system configured as described above has the interference generated by the interference between the light and the reference light through the two optical paths PS1 and PS2 to the master disk 116 for the production of the master disk 116. Three-dimensional hologram data is recorded in a pattern.

Light incident from the light source 100 (for example, laser light having a wavelength of 532 nm) is separated into two lights, that is, signal light and reference light, by the optical splitter 102 and is provided to the signal light path PS2 and the reference light path PS1. At this time, the optical splitter 102 reflects the signal light and transmits the reference light as it is and divides it into two optical paths.

The signal light separated by the optical separator 102 is irradiated to the master disk 116 through the first shutter 114, and the reference light is the first and second reflectors 104 and 106 and the second shutter located in the reference light path PS1. The master disk 116 is irradiated through 112.

When the reference light and the signal light are irradiated to the master disk 116, the master disk 116 is rotated by the motor 118 under the control of the controller 118, the rotating master disk 116 is caused by the interference between the reference light and the signal light The resulting interference fringe is recorded.

The controller 118 controls the first and second shutters 114 to open or close to prevent the signal light or the reference light from being incident on the master disk 116. For example, when the data to be recorded is "1", the first and second shutters 114 are controlled. , The shutters 2 are all opened, the reference light and the signal light are irradiated to the master disk 116 to record the interference fringe, and when the data to be recorded is "0", any one of the first and second shutters 114 ( Or all) to block either (or all) of the reference light and the signal light. In this way, since either of the reference light and the signal light is not irradiated to the master disk 116, no interference phenomenon occurs on the master disk 116, so that no interference fringe is recorded.

In addition, the controller 118 controls the actuator 108 to rotate the position of the second reflector 108 to control the angle of incidence of the reference light incident on the master disk 116. That is, the controller 118 records the interference fringe resulting from the interference between the reference light and the signal light having an arbitrary angle of incidence, and then rotates the second reflector 106 through the control of the actuator 108 to change the angle of incidence, and has a changed angle of incidence. An interference fringe resulting from the interference between the reference light and the signal light is recorded on the master disk 116. Using this method, the holographic master system manufactures the master disc 116 in a manner in which a plurality of interference fringes generated by reference light and signal light having different angles of incidence are recorded on one track, that is, angular superposition.

In the holographic master system for manufacturing a master disc of the present invention, the second shutter 112 is installed between the second reflecting mirror 106 and the master disc 116. It is provided between the 14 and 106 to supply or block the reference light to the master disk 116.

After that, the master disk 116 is used to produce a holographic ROM disk, and a manufacturing process thereof will be described with reference to FIG. 3. 3 is a structural diagram showing a holographic ROM disk manufacturing apparatus using a master disk according to the present invention.

As shown in FIG. 3, the holographic ROM disk manufacturing system 130 includes a light source 200 for generating signal light of a plane wave and a recording disc 130 for transmitting the signal light in the emission direction of the signal light generated from the light source 200. And a master disc 116 positioned at a rear end of the recording disc 130 to generate a reproduction light in response to the signal light transmitted through the recording disc 130 and provide the reproduction light to the recording disc 130.

The master disk 116 is a disk manufactured by the holographic master system shown in FIG. 2 and records an interference fringe generated by interference between a reference light and a signal light having a plurality of incident angles, and the recorded interference fringe is recorded. The signal light transmitted through the dragon disk 130 is diffracted to generate a plurality of reproduction light. The generated reproduction light is provided to the recording disc 130, and the incident angle of the reproduction light incident on the recording disc 130 is the same as the incident angle of the reference light when the master disc 116 is manufactured.

The recording disc 130 records interference fringes generated by interference between reproduction light having a plurality of incident angles incident from the master disc 116 and signal light provided from the light source 200.

As described above, according to the present invention, by manufacturing a holographic ROM disk using a master disk generated by an angular superposition method, it is not necessary to manufacture a mask pattern, thereby reducing the manufacturing cost and by diffraction at the time of passing through the mask. The cause of noise can be eliminated.

In addition, the present invention can reduce the manufacturing cost of the holographic ROM disk, since unlike the conventional optical system is not required.

Claims (4)

A light source for generating laser light, An optical separator that reflects a portion of the laser light and transmits another portion to separate the laser light into a reference light and a signal light; A first reflection mirror which reflects the reference light transmitted through the optical separator in a first optical path, A second reflection mirror for reflecting the reference light reflected by the first reflection mirror at a predetermined incident angle; An actuator connected to the second reflection mirror to drive the second reflection mirror to change an incident angle of the reference light; A master disk which is connected to a power source and rotates during data recording, and records an interference fringe generated by interference between signal light reflected by the optical splitter and reference light incident through the second reflection mirror; A first shutter for supplying or blocking the signal light reflected by the optical separator to the master disk; A control unit which controls the first shutter to block the signal light from being supplied to the master disk when the data is on, and controls the first shutter to supply the signal light to the master disk when the data is off. Holographic master system comprising a. The method of claim 1, The holographic master system further comprises a second shutter connected to the control unit and installed between the second reflecting mirror and the master disk and configured to supply or block the reference light to the master disk. The method of claim 1, The holographic master system further includes a second shutter connected to the control unit and installed between the first and second reflection mirrors and configured to supply or block the reference light to the master disk. A light source for generating a first signal light in the form of a plane wave; A recording disk disposed in the path of the signal light and transmitting the first signal light; An interference fringe generated by the interference between the reference light and the second signal light whose angle of incidence is changed is recorded, and diffracted by the first signal light transmitted through the recording disc to generate reproduction light, wherein the reproduction light is recorded at the incident angle. For master disks, And the interference fringe generated by the interference between the reproduction light and the signal light is recorded on the recording disc.

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