KR20040103118A - Apparatus for replicating holographic disk - Google Patents

Abstract

PURPOSE: A holographic disk copy device is provided to supply a recording reference light to a hologram medium by using a reference light path controller consisting of a rotative plate and a plane mirror, so that angle distributions of the reference light are equal to angle distributions of a reproduction reference light, thereby improving a reproduction efficiency. CONSTITUTION: A light source(200) generates a laser beam. A PBS(Polarizer Beam Splitter)(206) transmits a signal light while reflecting a reference light from the generated laser beam. The first reflecting mirror(210) reflects the transmitted signal light to the first optical path. A mask(222) modulates the reflected signal light in predetermined data patterns, and radiates the modulated signal light on a hologram medium(220). The second reflecting mirror(216) radiates the reflected reference light via the second and third optical paths. A reference light path controller(218) consists of a rotative plate rotated by an actuator, and a plane mirror for making the reference light incident at predetermined angle. The actuator controls an angle at which the reference light is incident on the hologram medium(220).

Description

Holographic Disk Replicator {APPARATUS FOR REPLICATING HOLOGRAPHIC DISK}

The present invention relates to a holographic ROM system, and more particularly, to a holographic disk replication apparatus capable of replicating a holographic disk having excellent bit error rate (BER).

1 is a block diagram of a typical holographic disk replicating apparatus of the related art, and includes a light source 100, a half wave plate (HWP) 102 and 112, a beam expander 104, and a polarizer beam splitter (PBS) ( 106, polarizers 108, 114, reflective mirrors 110, 116, 117, mask 122, hologram medium 120, conical mirror 118.

The light source 100 is a laser source having a predetermined wavelength, for example, a wavelength of 532 nm, and generates laser light required for holography.

The laser light generated from the light source 100 is provided to the PBS 106 via the HWP 102, the light expander 104, and the like.

The PBS 106 is a structure in which two or more kinds of materials having different refractive indices are repeatedly deposited. The PBS 106 transmits signal light and reflects reference light.

The signal light transmitted through the PBS 106 is reflected by the reflecting mirror 110 through the polarizer 108, and the reflected signal light is transmitted through the mask 122 and modulated in a predetermined pattern to the hologram disk 120. Is investigated. The reference light reflected through the PBS 106 is reflected by the reflection mirrors 116 and 117 via the HWP 112 and the polarizer 114 and irradiated to the conical mirror 118.

The conical mirror 118 is a means for controlling playback at the same angle during reproduction of the holographic disc reproducing system, and multiplexing of the reproduction angles is possible using conical mirrors having different angles.

At this time, since the holographic disk duplication apparatus cannot configure the conical mirror 118 using a separate holder, the conical mirror 118 must be attached directly to the holographic medium 120. However, when multiplexing the system, the conical mirror 118 and the hologram medium 120 must be separated and mounted as conical mirrors that inject the reference light into the hologram medium 120 at different angles.

However, separating the conical mirror 118 from the hologram medium 120 is not only difficult because it requires a high degree of precision, but also has a problem that a lot of time is consumed.

In this manner, the holographic disc duplication apparatus records data on the hologram medium 120 by an angular multiplexing technique, and the hologram medium 120 on which the data is recorded is reproduced by the holographic disc reproducing apparatus. The holographic disc reproducing apparatus uses a phase conjugation reproducing technique to reproduce data recorded on the hologram medium 120.

The conical mirror 118, which changes the incident angle and path of the recording reference light in the holographic disk replicating apparatus, uses a cone diameter, so that the angle at which the recording reference light incident at a specific position of the cone diameter is incident on the hologram medium 120. The distribution has a structure that spreads around a reference point at a specific position of the cone. In this case, the angle of diffusion becomes larger as the distance between the conical mirror 118 and the hologram medium 120 increases.

However, since the holographic disc reproducing apparatus reproduces the data recorded on the hologram medium 120 using the phase conjugate wave reproducing technique, the angular distribution of the reproduction reference light has a parallel structure.

For this reason, as shown in Fig. 2, there occurs a case where the angle distribution of the reference light at the time of recording and the angle distribution of the reference light at the time of reproduction are different. This becomes a factor of reducing the reproduction diffraction efficiency of the holographic disc during reproduction in the holographic disc reproducing apparatus.

Accordingly, the present invention has been made to solve the above-described problem, by applying a rotating mirror instead of a conical mirror, it is possible to improve the reproduction diffraction efficiency of the holographic disc while realizing the ease of device manufacturing and multiplexing It is an object of the present invention to provide a holographic disk replication apparatus capable of replicating a holographic disk.

In order to achieve the above object, the present invention provides a holographic disk replication apparatus comprising: a light source for generating a laser light required for holographic; and a PBS (Polarizer) for transmitting signal light and reflecting reference light from the laser light generated from the light source. A beam splitter, a first reflection mirror for reflecting the signal light transmitted through the PBS in a first optical path, a mask for modulating the signal light reflected by the first reflection mirror into a predetermined data pattern and irradiating the hologram medium; And a second reflection mirror for irradiating the reference light reflected through the PBS via second and third optical paths, and a light transmitting region corresponding to the width of the reference light reflected by the second reflection mirror, and being rotated by an actuator. It is installed on the rotating disk and the path of the reference light transmitted through the light transmitting area, and at the same time when the rotating disk is rotated A reference light path adjusting unit comprising a flat mirror for transmitting the reference light at a predetermined angle, and an actuator for adjusting an angle at which the reference light, which is made with the flat mirror and tilts the flat mirror, is adjusted to the hologram medium. Include.

1 is a block diagram of a typical typical holographic disk duplication apparatus,

2 is an exemplary diagram for describing an angular distribution of reference light incident on a conventional holographic disc.

3 is a block diagram of a holographic disk duplication apparatus according to a preferred embodiment of the present invention;

4 is a view showing in detail the reference light path control unit in the holographic disk replication apparatus according to the present invention,

5 is an exemplary diagram for explaining an angular distribution of reference light incident on a disk of the holographic disk duplication apparatus according to the present invention.

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

200: light source 202, 212: HWP

204: optical expander 206: PBS

208, 214: polarizers 210, 216, 217: reflective mirrors

218: reference light path control unit 220: hologram medium

222: mask

The above and other objects and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention described below with reference to the accompanying drawings by those skilled in the art.

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

3 is a block diagram illustrating a holographic disk duplication apparatus according to a preferred embodiment of the present invention, FIG. 4 is a view showing in detail the reference light path control unit in the holographic disk duplication apparatus according to the present invention, FIG. It is an exemplary view for explaining the angular distribution of reference light incident on the hologram medium of the holographic disk duplication apparatus according to the present invention.

As shown in FIG. 3, the holographic disk replicating apparatus includes a light source 200, HWPs 202 and 212, an optical expander 204, a PBS 206, polarizers 208, 214, and a reflection mirror 210. 216, 217, a mask 222, a hologram medium 220, and a reference light path controller 218.

First, the present invention is applied to the reference light path control unit 218 consisting of a rotating disk and a flat mirror instead of the conventional conical mirror 118, the rest of the system configuration and the light path is the same as the conventional holographic ROM system, Duplicate explanations will be omitted.

The reference light path adjusting unit 218 according to the present invention injects the recording reference light having the same angle distribution as the angle distribution when the reproduction reference light is incident on the hologram medium 220 to the hologram medium 220.

That is, as shown in FIG. 3, the signal light reflected from the reflection mirror 210 through the PBS 206 and the polarizer 208 is modulated by the mask 222 to be incident on the hologram medium 220, and the PBS ( 206, the reference light reflected by the mirrors 216 and 217 through the HWP 212 and the polarizer 214 passes through the reference light path adjusting unit 218 and enters the hologram medium 220 to be recorded.

As shown in FIG. 4, the reference light path adjusting unit 218 has a light transmitting area 218c corresponding to the width of the reference light reflected from the mirror 217 in a predetermined area, and is rotated by the rotary actuator 218d. A rotating mirror 218a and a planar mirror 218e installed on a path of the reference light passing through the light transmission region 218c and deflecting the reference light at a predetermined angle. The plane mirror 218e can be adjusted by tilting the connected actuator 218f. At this time, the planar mirror 218e is installed in connection with the central axis 218b, which is a lower region of the light transmitting region 218c, from the central axis 218b of the rotating disk 218a, and when the rotating disk 218a is rotated. Is rotated together.

The rotary actuator 218d is installed at the end of the central axis 218b of the rotating disk 218a to rotate the rotating disk 218a when recording data on the hologram medium 220 and to rotate the light transmitting region 218c. The flat mirror 218e installed in the lower area is also rotated.

The operation process of the holographic disk duplication apparatus having such a structure is as follows.

First, when data starts to be recorded on the hologram medium 220, the rotating disc 218a starts to rotate at a high speed by the rotary actuator 218d of the reference light path adjusting unit 218. At this time, when the rotational disc 218a reaches a predetermined rotation speed, the recording reference light is irradiated onto the rotational disc 218a, and a part of the irradiated recording reference light forms the light transmitting region 218c formed on the rotational disc 218a. A flat mirror 218e is reached through.

Subsequently, the recording reference light reaching the planar mirror 218e is reflected at a predetermined angle by the planar mirror 218e and is incident on the hologram medium 220, and at the same time, the mirror 210 installed at the bottom of the hologram medium 220. The signal light carrying data to be recorded through the incident light is incident on the hologram medium 220 through the mask 222.

Through this process, data is primarily recorded on the hologram medium 220.

As described above, the present invention reflects the recording reference light provided when the holographic disk is reproduced at a predetermined angle using the planar mirror 218e and enters the hologram medium 220, thereby providing the recording reference light to the hologram medium 220. The angular distribution at the time of making, as shown in Fig. 5, has the same parallel structure as the angular distribution of the reproduction reference light.

Then, in order to record the next data, the plane mirror 218e is tilted with the actuator 218f to change the angle at which the recording reference light is reflected, that is, the angle of the recording reference light incident on the hologram medium 220, and the above process. Repeat to overwrite the next data.

As described above, the present invention provides a reference light for recording on the hologram medium by using a reference light path control unit consisting of a rotating disk and a flat mirror to make the angle distribution of the recording reference light equal to the angle distribution of the reference light for reproduction, thereby reproducing in a player. In addition to improving efficiency, high-reliability holographic disc replication is possible.

In addition, the present invention changes the angle at which the recording reference light is incident on the hologram medium using a planar mirror, so that the angle overlapping recording is possible without replacement, unlike the conventional and conical mirrors.

As mentioned above, although this invention was demonstrated concretely based on the Example, this invention is not limited to this Example, Of course, various changes are possible within the range which does not deviate from the summary of the claim described below. .

Claims (1)

In the holographic disk duplication apparatus, A light source for generating laser light required for holographic, Polarizer Beam Splitter (PBS) for transmitting signal light and reflecting reference light from the laser light generated from the light source; A first reflection mirror reflecting the signal light transmitted through the PBS to a first optical path; A mask for modulating the signal light reflected by the first reflection mirror into a predetermined data pattern to irradiate the hologram medium; A second reflection mirror that irradiates the reference light reflected through the PBS through second and third optical paths; A rotational disk provided with a light transmission area corresponding to the width of the reference light reflected by the second reflection mirror and rotated by an actuator, and installed on a path of the reference light transmitted through the light transmission area and simultaneously rotated when the rotation disk is rotated. A reference light path control unit which is rotated and made of a planar mirror for incident the reference light at a predetermined angle; An actuator configured to adjust the angle at which the reference light incident to the plane mirror is adjusted by tilting the plane mirror to be incident on the hologram medium; Holographic disk replication apparatus comprising a.