KR100280943B1 - Hologram data storage system for recording / playback on two sides simultaneously - Google Patents

Abstract

The present invention relates to a hologram data storage system for simultaneously recording / reproducing two surfaces, comprising: a laser for oscillating a laser beam; Optical separation means for separating the laser beam into a first object light and a first reference light, and a second object light and a second reference light; Spatial light modulating means for modulating the first object light and the second object light; Optical switching means for opening and closing the passage of the beam; Light guiding means for guiding the progress of the beam; And a hologram recording medium having a beam absorbing layer formed at an intermediate portion of both recording portions for simultaneously recording the first object light and the first reference light, and the second object light and the second reference light, wherein the beam absorbing layer of the hologram recording medium is included. is formed of a material a mixture of FeO in the material in a mixture of FeO _{Na 2 O-Cao-SiO 2} , and _{Na 2 O-Cao-SiO 2} -P 2 O 5 -Al 2 O 3.

This invention has the advantage of reducing the recording time by 1/2, and at the same time has the advantage that can display two sides.

Description

HOLOGRAM DATA STORAGE SYSTEM FOR WRITING / READING 2 PAGE AT ONE TIME

The present invention relates to a holographic data storage system for recording / reproducing two surfaces simultaneously, and in particular, by recording / reproducing two pages simultaneously on a photorefractive material using a plurality of object lights, the recording time is cut in half and multimedia. A hologram data storage system that simultaneously records / reproduces two surfaces to perform a function as a multimedia.

With the advent of the multimedia era, holographic memory is drawing attention as the need for a system that records a lot of information and requires fast data transfer increases.

Such holographic recording records not only the intensity but also the phase of the object light reflected from the object, and the intensity and phase of the light of the object is constituted by the interference of the object light and the reference light. The object light and the reference light form an interference fringe, and the interference fringes thus formed are recorded in a material responding to the intensity of the interference fringe, and the hologram, which is a three-dimensional image of the object, is reproduced by irradiating the reference light on the recorded interference fringe.

The hologram is stored in the cube and only the reference light used in the recording process can read the hologram recorded in the cube, and the reference light having a different wavelength and phase from the reference light used in the recording passes through the hologram recorded in the cube without any effect. .

Using the natural nature of volume holograms, it is possible to store vast amounts of data inside small cubes by recording many holograms in the same place of the storage material with different reference lights. One method of making another reference light is the Angle Multiplexing method in which the angle of the reference light is changed at each recording time. This method allows you to store hundreds to thousands of holograms organized in pages of binary data in the same place. That is, by recording and reproducing a lot of data in the unit of a page in the same place, recording and reproducing with a high storage density and a fast data transfer rate are possible, thereby enabling a digital data storage system using holography.

FIG. 1 shows a conventional 90 ° geometry holographic digital data storage system. As shown in FIG. 1, a laser beam 11 generated by the laser 10 is beamed. The light incident on the splitter 20 is divided into the reference light 12 and the object light 13, and the object light 13 is a spatial light modulator (SLM) in units of one page of binary data of light and dark, which are formed by pixels according to input data. Modulated by a Spatial Light Modulator (50), the reference light 12 correspondingly changing the angle of the rotating mirror 30 little by little is created on each page.

Afterwards, the object light 13 and the reference light 12 cause interference in the hologram recording medium 60 for recording the hologram, and the mineral oil of the kinetic charges in the hologram recording medium 60 according to the intensity of the interference pattern generated at this time. The degree phenomenon occurs and the interference pattern is recorded through this process. In order to read the data recorded on the hologram recording medium 60, only the reference light 12 is irradiated onto the hologram recording medium 60, and the interference pattern is diffracted by the reference light 12 to restore a checkered pattern composed of the contrast of the original pixel. Afterwards, the read image is reflected on the CD (Charge Coupled Device) 70 to restore the original data.

Such a conventional 90-degree batch holographic data storage system is capable of recording / reproducing only one surface, and thus has a problem in that storage capacity is lower than that of the present invention described later.

The present invention has been devised to solve the above-mentioned defects and problems, and the recording time is reduced by half by recording / reproducing two pages simultaneously on a photorefractive material using a plurality of object lights. It is an object of the present invention to provide a hologram data storage system that simultaneously records / reproduces two surfaces capable of performing functions as a multimedia.

In order to achieve the above object, the present invention is a laser for oscillating a laser beam; Optical separation means for separating the laser beam into a first object light and a first reference light, and a second object light and a second reference light; Spatial light modulating means for modulating the first object light and the second object light; Optical switching means for opening and closing the passage of the beam; Light guiding means for guiding the progress of the beam; And a hologram recording medium having a beam absorbing layer formed at an intermediate portion of both recording units for simultaneously recording the first object light and the first reference light and the second object light and the second reference light.

Further, the beam absorption layer material a mixture of FeO in the Na ₂ O-Cao-SiO ₂ mixed with FeO in the material, and the _{Na 2 O-Cao-SiO 2} -P 2 O 5 -Al 2 O 3 of the hologram recording medium Is formed.

1 is a block diagram of a conventional hologram data storage system.

2 is a block diagram of a hologram data storage system according to the present invention.

3 is a block diagram of a hologram recording medium.

<Description of the symbols for the main parts of the drawings>

100: laser 110: first beam splitter

111: first shutter 120: second beam splitter

121: second shutter 122: third shutter

123: mirror 130: third beam splitter

131: mirror 140,150: first and second spatial light modulator

160,170: first and second photoelectric conversion element 200: hologram recording medium

201, 202: both recording sections 203: beam absorbing layer

B: laser beam B1: one side beam

B2: other beam B3: first object light

B4: first reference light B5: second object light

B6: second reference light

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

2 is a block diagram of a hologram data storage system according to the present invention, and FIG. 3 is a block diagram of a hologram recording medium. As shown in the drawing, the hologram data storage system of the present invention is a laser beam (B). A laser (100) for oscillating; Optical separation means for separating the laser beam B into a first object light B3 and a first reference light B4, and a second object light B5 and a second reference light B6; Spatial light modulating means for modulating the first object light (B3) and the second object light (B5); Optical switching means for opening and closing the passage of the beam; Light guiding means for guiding the progress of the beam; Beams in the middle of both recording units 201 and 202 for simultaneously recording the first object light B3 and the first reference light B4 and the second object light B5 and the second reference light B6. And a hologram recording medium 200 having an absorbing layer 203 formed thereon.

The optical separation means includes: a first beam splitter (110) for separating the laser beam (B) into beams (B1) and (B2); A third beam splitter 130 for separating the one side beam B1 into the first object light B3 and the first reference light B4; And a second beam splitter 120 for separating the other beam B2 into the second object light B5 and the second reference light B6, wherein the spatial light modulating means comprises: the first object light B3; The first and second spatial light modulators 140 and 150 are provided on the respective optical paths for spatial light modulation of the second object light B5 and are operated when recording signals.

The light opening and closing means includes: a first shutter 111 for opening and closing one side beam B1 of the first beam splitter 110; A second shutter 121 for opening and closing the second reference light B6; It consists of a third shutter 122 for opening and closing the second object light (B5), the light guide means is configured by arranging the mirrors 123, 131 on the optical path of the beam.

More specifically, in the present invention, the first beam splitter 110 for separating the laser beam B generated by the laser 100 into the beams B1 and B2 is disposed on the optical path of the laser beam B. The third beam splitter 130 for separating the one side beam B1 into the first object light B3 and the first reference light B4 is disposed on the optical path of the beam B1, and the other side beam B2 is disposed. A second beam splitter 120 for separating the second object light B5 and the second reference light B6 is installed on the optical path of the other beam B2, and the first object light B3 and the second object are separated. On the optical path of the light B5, for example, the first and second spatial light modulators 140 and 150, such as an LCD, or the first and second photoelectric conversion elements 160, such as a CDC, may be used. , 170 are installed.

The hologram recording medium 200 is provided at a position where the first object light B3 and the second object light B5 and the first reference light B4 and the second reference light B6 meet.

The first shutter 111 is disposed on the one-side beam B1 optical path of the first beam splitter 110, and the second shutter 121 is disposed on the second reference light B6 optical path of the second beam splitter 120. The third shutter 122 and the mirror 123 are disposed on the optical path of the second object light B5 of the second beam splitter 120, and the optical path of the first reference light B4 of the third beam splitter 130 is provided. The mirror 131 is disposed on the top.

The hologram recording medium 200 has a beam absorbing layer 203 formed in the middle of both recording units 201 and 202, and an absorption material constituting the beam absorbing layer 203 varies depending on the wavelength. example when using infrared _{(IR) Na 2 O - Cao} - using a material of a mixture of FeO 1~3w / o on SiO _{2 or, Na 2 O - Cao - SiO} 2 - P 2 O 5 - Al 2 O 3 A material obtained by mixing FeO of 1 to 3 w / o is used.

As described above, the hologram data storage system of the present invention opens and records the first shutter 111 and the third shutter 122, and at this time, the laser beam B generated by the laser 100 is The beam B1 and B2 are separated by the first beam splitter 110, and the one side beam B1 is separated by the third beam splitter 130 by the first object light B3 and the first reference light B4. After the first reference light B4 is reflected by the mirror 131, the first reference light B4 reaches the recording unit 201 of the hologram recording medium 200, and the first object light B3 passes through the first spatial light modulator. It is modulated by 140 to reach one side recording unit 201 of the hologram recording medium 200 and recording is performed on one side recording unit 201. The other beam B2 separated by the first beam splitter 110 is divided into a second object light B5 and a second reference light B6 by the second beam splitter 120, and then a second reference light. (B6) reaches the other recording unit 202 of the hologram recording medium 200 and the second object light (B5) is modulated by the second spatial light modulator 150 and the other recording unit of the hologram recording medium 200 202 is reached and recording is performed in the other recording unit 202. Therefore, the recording is performed simultaneously on both recording units 201 and 202 of the hologram recording medium 200.

On the other hand, when reproducing, the hologram recording medium 200 is inverted by 180 degrees to reproduce the reproducing stage recorded by the first spatial light modulator 140 by the second photoelectric conversion element 170, and the second spatial light modulator 150 is reproduced. The reproducing end recorded at &quot; is reproduced by the first photoelectric conversion element 160.

The present invention as described above has the advantage of reducing the recording time by 1/2, and at the same time has the advantage of displaying two sides.

While the embodiments of the present invention have been described so far, the present invention is not limited thereto, and various embodiments which can be modified and changed within the true spirit and scope of the principles described and claimed are within the protection scope of the present invention. You will have to understand.

Claims (3)

A laser (100) for oscillating the laser beam (B); Optical separation means for separating the laser beam B into a first object light B3 and a first reference light B4, and a second object light B5 and a second reference light B6; Spatial light modulating means for modulating the first object light (B3) and the second object light (B5); Optical switching means for opening and closing the passage of the beam; Light guiding means for guiding the progress of the beam; Beams in the middle of both recording units 201 and 202 for simultaneously recording the first object light B3 and the first reference light B4 and the second object light B5 and the second reference light B6. A hologram data storage system for recording / reproducing two surfaces simultaneously, comprising a hologram recording medium (200) having an absorbent layer (203) formed thereon. The optical beam splitter (110) of claim 1, further comprising: a first beam splitter (110) disposed on an optical path of the laser beam (B) to separate the laser beam (B) into beams (B1) and (B2); A third beam splitter 130 disposed on the optical path of the one beam B1 to separate the one beam B1 into the first object light B3 and the first reference light B4; And a second beam splitter 120 disposed on the optical path of the other beam B2 to separate the other beam B2 into the second object light B5 and the second reference light B6, and the spatial light modulation. The means are provided on the respective optical paths for spatial light modulation of the first object light (B3) and the second object light (B5), and the first and second spatial light modulators (140) are operated when recording signals. And a hologram data storage system for recording / reproducing two sides simultaneously. The optical switch of claim 2, further comprising: a first shutter (111) disposed on an optical path of one beam (B1) of the first beam splitter (110); A second shutter (121) disposed on an optical path of a second reference light (B6) of the second beam splitter (120); And a third shutter 122 disposed on an optical path of the second object light B5 of the second beam splitter 120, and the light guide means includes a second object light of the second beam splitter 120. B5) a mirror 123 disposed on the optical path; A mirror 131 disposed on an optical path of the first reference light B4 of the third beam splitter 130, The beam absorbing layer 203 of the hologram recording medium 200 may contain ₁ to ₃ w / o of FeO in Na ₂ O—Cao-SiO ₂ or Na ₂ O—Cao-SiO ₂ -P ₂ O ₅ -Al ₂ O ₃ . A hologram data storage system for simultaneously recording / reproducing two surfaces, characterized by being formed of a mixed material.