KR20090002585A - Apparatus for processing optical information, method of prcessing optical information thereof - Google Patents

Abstract

An optical information processing apparatus and an optical information processing method using the same are provided to reduce the number of reflective members and lenses, thereby cutting down on the manufacturing cost. An optical information processing apparatus comprises a light source(100), a beam splitter, a signal beam optical system(120) guiding the signal beam in which data is loaded to a storage medium, a reference beam optical system(130) dividing the path of recording reference beam and reproduction reference beam, a recording reference beam optical system(140) guiding the recording reference beam to the storage medium, a reproduction reference beam optical system(150) guiding the reproduction reference beam to the storage medium, and a detector(160) detecting the light information reproduced in the storage medium.

Description

Optical information processing apparatus and optical information processing method using the same {Apparatus for processing optical information, method of prcessing optical information about}

The present invention relates to an optical information processing apparatus and an optical information processing method using the same, and more particularly, to an optical information processing apparatus for forming a phase conjugate wave of a reference light used in recording optical information by adjusting an angle of a rotating mirror and an optical using the same. It relates to an information processing method.

With the development of the multimedia industry and the telecommunications industry, the modern society is capable of storing data of very large capacity and processing data at high speed. Among such information processing technologies, optical information data processing apparatuses using optical information processing techniques include DVD (Digital Versatile Disc), HD-DVD, Blu-ray (BD), Near field light processing device, and holographic light processing device. . Among them, the holographic optical processing apparatus has a large storage capacity because a plurality of information pages recorded as holographic images are superimposed on a recording medium in a volume form. In the holographic optical processing apparatus, optical information is recorded by an interference pattern generated by irradiating optically modulated signal light and reference light on the recording medium, and the optical information is reproduced by diffraction generated by irradiating the recording medium with the reference light used at the time of recording. .

At this time, if the phase conjugated beam of the reference light used for recording the optical information is used as the reference light for reproducing the optical information, the image causing the distortion of the signal light during data recording is reversely compensated and the image is imaged as it is. . The phase conjugate wave can be made by changing the direction of propagation of the beam in the opposite direction when the reference light is parallel light.

Prior art for reproducing optical information by irradiating such a phase conjugate wave to a recording medium is disclosed in US Patent Application No. 2002-0057486 Spatial light modulator / demodulator and holographic recording / reproducing appratus using the same. In the case of the U.S. Patent Application Publication, the data is reproduced by irradiating a phase conjugate wave in a direction opposite to the traveling direction of the reference light used for recording on the recording medium.

As described above, in order to form a phase-conjugated wave, a large number of reflecting members, lenses, etc. are required, which makes the configuration of the reference light optical system complicated, and provides the phase-conjugated wave to the storage medium in a direction opposite to the traveling direction of the reference light when recording. In order to adjust the incident environment of the phase conjugate wave to be the same as the incident environment of the reference light incident on the recording medium at the time of recording, there is a problem in that the installation is difficult.

An optical information processing apparatus according to the present invention for achieving the above object includes a light source, an optical splitter for separating the light emitted from the light source into a signal light and a reference light, and loading the data into the signal light, and the signal light loaded with the data. A signal light optical system for guiding the storage medium to the storage medium, and dividing the reference light into a recording reference light and a reproducing reference light, and setting an angle so that the reproducing reference light becomes a phase conjugate wave of the recording reference light. A reference light optical system for dividing a path of a reference light, a recording reference light optical system for guiding the recording reference light to the storage medium, a reproducing reference light optical system for guiding the reproducing reference light to the storage medium, and the reproducing reference light in the storage medium. And a detector for detecting the reproduced light information.

The signal light optical system includes a signal light shutter for passing the signal light when recording the optical information, an optical splitter for separating the signal light reflected by the reflection mirror according to polarization, and a light for loading data into the signal light separated from the optical splitter. A modulator, a quarter wave plate for changing the polarization of the signal light loaded with the data, a half wave plate for changing the polarization of the signal light with the polarization changed by the quarter wave plate, and the signal light whose polarization is changed by the half wave plate It may include an objective lens to convert.

The reference light optical system reflects the reference light and uses the reference light for recording, and sets the angle so that the reproduction reference light becomes a phase conjugate wave of the recording reference light, and the recording reference light reflected by the rotating mirror. It may include a light splitter for separating the reproduction reference light.

The phase conjugate wave may be formed by reflecting the recording reference light at an angle symmetric with a reflection angle reflected from the rotation mirror about a linear direction perpendicular to the angle at which the recording reference light is incident on the rotation mirror. .

The recording reference light optical system may include a recording reference light shutter for passing the recording reference light when the optical information is recorded, and a half-wave plate for changing the polarization of the recording reference light passing through the recording reference light shutter.

The reproduction reference light optical system may include a reproduction reference light shutter for passing the reproduction reference light when the optical information is reproduced, and a half-wave plate for changing the polarization of the reproduction reference light passed through the reproduction reference light shutter.

The optical information is a holographic interference fringe recorded in multiplexes, and the multiple recording of the optical information may be performed by adjusting the angle of the rotating mirror.

The optical information processing method according to the present invention for achieving the above object is to separate the light provided from the light source into a signal light and a reference light, to load the data into the signal light incident on the storage medium, the reference light incident on the storage medium Recording the optical information, setting an angle of the rotating mirror to form a phase conjugated wave of the reference light, and irradiating the phase-conjugated wave formed by the rotating mirror to the storage medium on which the optical information is recorded. And detecting the reproduced light reproduced by the phase conjugate wave.

The phase conjugate wave may be formed by reflecting the reference light at an angle symmetric with a reflection angle reflected from the rotation mirror with respect to a linear direction perpendicular to the angle at which the reference light is incident on the rotation mirror.

The reference light incident on the storage medium and the phase conjugate liquid wave incident on the storage medium may coaxially travel to the storage medium in opposite directions.

The optical information processing method according to the present invention for achieving the above object comprises the steps of separating the light provided from the light source into a signal light and a reference light, the rotation mirror to use the reference light as a recording reference light for recording the optical information at any angle The reference light is reflected by the rotating mirror, and the data is loaded onto the signal light to enter a storage medium, and the recording reference light is incident to the storage medium to record optical information. .

By adjusting the angle of the rotating mirror, the optical information may be recorded in multiple times on the storage medium.

The optical information processing method according to the present invention for achieving the above object comprises the steps of setting the angle of the rotation mirror so that the reproduction reference light is formed as a phase conjugate wave of the recording reference light used when recording the optical information, wherein the rotation mirror formed by the rotation mirror Irradiating a phase-conjugated wave to a storage medium on which the optical information is recorded and detecting the reproduced light reproduced by the reproducing reference light.

The phase conjugate wave may be formed by reflecting the recording reference light at an angle symmetric with a reflection angle reflected from the rotation mirror with respect to a linear direction perpendicular to the angle at which the recording reference light is incident on the rotation mirror.

The reproduction reference light incident on the storage medium may be incident on the storage medium in the opposite direction and coaxial with the recording reference light irradiated to the storage medium when the optical information is recorded.

The reproduction of the optical information may be reproduced in multiple times in the storage medium by adjusting the angle of the rotating mirror.

The optical information processing apparatus according to the present invention and the phase conjugate wave of the reference light used when recording the optical information using the same can be easily formed to increase the reproduction efficiency of the optical information to be reproduced, and thus the phase of the reference light used when recording the optical information. It is possible to reduce the configuration of a plurality of reflecting members and lenses to produce a conjugate wave, thereby reducing the manufacturing cost of the optical information processing device and simplifying and miniaturizing the system of the optical information processing device.

Hereinafter, an optical information processing apparatus according to an embodiment of the present invention configured as described above will be described.

1 is a block diagram showing an optical information processing apparatus according to an embodiment of the present invention. As shown in FIG. 1, the optical information processing apparatus records a light source 100, a first light splitter 110 that separates light into signal light and reference light, a signal light optical system 120 that provides a path to signal light, and a reference light for reproduction. A reference light optical system 130 formed of a phase-conjugated wave of the reference light used for recording, dividing a path between the reference light for recording and the reference light for reproduction, and a recording reference light optical system 140 for guiding the recording reference light to the storage medium 170, and reproduction. The reproduction reference light optical system 150 for guiding the reference light for the storage medium 170, and a detector 160 for detecting the optical information reproduced from the storage medium 170.

The light source 100 emits light including both P-polarized light and S-polarized light, and the first light splitter 110 divides the light emitted from the light source 100 into a light split ratio set by a user to convert the light into a signal light and a reference light. It is a non-polarization light splitter to separate.

The signal light optical system 120 is positioned in the path of the signal light separated from the light by the first light splitter 110. The signal light optical system 120 includes a signal light shutter 121 for passing and blocking signal light, a first reflection mirror 122 for guiding the signal light to the optical modulator 125, and a second light splitter for reflecting and transmitting the signal light according to polarization ( 123, a quadrature wave plate 124 for changing the polarization of the signal light reflected by the second light splitter 123, an optical modulator 125 for loading data into the signal light, and a quadrature wave plate 124. A first half wave plate 126 for changing polarization and an objective lens 127 for Fourier transforming signal light are provided.

The signal light shutter 121 is opened so that the signal light can be irradiated to the storage medium 170 when the optical information is recorded, and is shielded so that the signal light is blocked when the recorded optical information is reproduced. The first reflection mirror 122 for guiding the signal light to the second light splitter 123 is positioned in the path of the signal light passing through the signal light shutter 121.

The second light splitter 123 transmits the signal light of the P polarization from the signal light including the P polarization and the S polarization to the photodetector 160, and reflects the signal light of the S polarization to the optical modulator 125. It is a light splitter. The optical modulator 125 is a reflection type optical modulator that loads data in the signal light and reflects the signal light toward the second light splitter 123. Between the second light splitter 123 and the optical modulator 125 is a quadrature plate 124 for modulating the polarization of the signal light loaded with data into P-polarized light. In another embodiment, there may be a method of installing the quarter wave plate 124 in the optical modulator 125.

The first half-wave plate 126 that modulates the P-polarized signal light into S-polarized light is located in the path through which the signal light modulated by P polarization is located, and the path of the S-polarized signal light that has passed through the first half-wave plate 126 travels. An objective lens 127 for Fourier transforming the signal light is provided.

On the other hand, the reference light optical system 130 is positioned in the path of the reference light separated by the first light splitter 110. The reference light optical system 130 reflects the recording reference light used for recording the optical information, and rotates the mirror 131 to adjust the angle to form a phase conjugate wave of the recording reference light used for recording the reference reference light used for reproducing the optical information And a first lens 132 for guiding the reference light reflected by the rotating mirror 131 and a third light splitter 133 for dividing the path between the recording reference light and the reproduction reference light. The third light splitter 133 is a polarized light splitter that reflects S-polarized light and transmits P-polarized light among recording reference light for optical information recording.

The recording reference light optical system 140 is positioned in the path of the recording reference light separated by the third light splitter 133. The recording reference light optical system 140 polarizes the recording reference light shutter 141 for blocking and passing the recording reference light passed through the third light splitter 133 and the recording reference light passing through the recording reference light shutter 141. And a second reflecting mirror 144 and a second lens 143 for guiding the recording reference light transmitted through the second half wavelength plate 142 to the storage medium 170.

The first lens 132 and the second lens 143 adjust the focal length of the recording reference light so that the recording reference light can be irradiated at a position where the signal light is irradiated onto the storage medium 170.

Meanwhile, the reproduction reference light optical system 150 is positioned in the path of the reproduction reference light separated by the third light splitter 133. The reproduction reference light optical system 150 includes a reproduction reference light shutter 151 for passing and blocking the reproduction reference light, a third half wave plate 152 for changing the polarization of the reproduction reference light, and a reproduction reference light to the storage medium 170. It includes a third reflecting mirror 153 and a third lens 154 to guide.

The first lens 132 and the third lens 154 adjust the focal length so that the phase conjugate wave of the recording reference light can be irradiated at the position where the optical information is recorded.

In this case, a reflecting member and a lens may be additionally disposed to adjust the conditions such that the focal lengths of the first lens 132 and the second lens 143 and the first lens 132 and the third lens 154 match. The reflective member and the lens may be additionally disposed so that the conditions of the two lenses 143 and the storage medium 170 and the third lens 154 and the storage medium 170 are the same.

A detector 160 for detecting optical information is located in the path of the reproduction light reproduced by the storage medium 170 by the reproduction reference light. The detector 160 may be a charge-coupled device (CCD), a complementary metal-oxide semiconductor (CMOS), or other optical device capable of photodetection.

Hereinafter, the optical information processing method in the optical information processing apparatus according to the preferred embodiment of the present invention configured as described above will be described.

2 is a view showing an operation when recording optical information in the optical information processing apparatus according to an embodiment of the present invention, Figure 3 is a view showing an operation during optical information reproduction in the optical information processing apparatus according to an embodiment of the present invention 4 through 6 are flowcharts illustrating an optical information processing method according to an exemplary embodiment of the present invention.

As shown in FIGS. 2 and 4 to 6, when the light source 100 emits light including both P-polarized light and S-polarized light, the first light splitter 110 splits the light by the set light splitting ratio, thereby causing signal light and reference light. To form (S100).

At this time, the signal light shutter 121 positioned in the signal light optical system 120 is opened to pass the signal light, and the signal light passing through the signal light shutter 121 enters the second light splitter 123 by the first reflection mirror 122. . The signal light of P polarization is transmitted toward the detector 160 among the signal light including P polarization and S polarization incident to the second light splitter 123, and the signal light of S polarization is reflected and directed to the optical modulator 125.

The signal light of the S-polarized light on which data is loaded by the optical modulator 125 is reflected, and the polarization is changed to P-polarized light by the quarter-wave plate 124 located between the second light splitter 123 and the optical modulator 125. It passes through the second light splitter 123. The P-polarized signal light transmitted through the second light splitter 123 is changed into S-polarized light by the first half-wave plate 126, and Fourier-converted by the objective lens 127 to record the optical information of the storage medium 170. Is incident on.

Meanwhile, in order to use the reference light divided by the first light splitter 110 as the reference light for recording, the angle of the rotation mirror is set (S111).

The reference light is reflected by the rotation mirror 131, and passes through the first lens 132 to be directed to the third light splitter 133. The reference light of the S-polarized light reflected by the third light splitter 133 is blocked by the reproduction reference light shutter 151, and the reference light of the P-polarized light transmitted through the third light splitter 133 is used as the recording reference light. The recording reference light changes to S-polarized light while passing through the second half-wave plate 142, and a focal length is formed by the second lens 143.

Thereafter, the recording reference light is reflected by the second reflection mirror 144 and is incident on the storage medium 170 (S112). At this time, the recording reference light and the signal light incident on the storage medium 170 form a holographic interference fringe on the storage medium 170 by interference with each other to record optical information (S110). In addition, by controlling the angle of the rotating mirror 145, the interference fringe may be recorded in the storage medium 170.

3 and 4 to 6, the signal light shutter 121 is shielded to block the signal light when the optical information is reproduced.

At this time, the angle of the rotation mirror 131 is adjusted to form the reference light used for optical information reproduction as a phase conjugate wave of the reference light for recording used for optical information recording (S121).

Subsequently, when the reference light is irradiated to the rotating mirror 131, a phase conjugate wave of the recording reference light used when recording the optical information is formed (S120). The phase conjugate wave, which is a reproduction reference light, passes through the first lens 132 and proceeds to the third light splitter 133.

The phase-conjugated wave of the P-polarized light transmitted through the third light splitter 133 is blocked by the recording reference light shutter 141, and the phase-conjugated wave of the S-polarized light reflected by the third light splitter 133 is the reference light shutter for reproduction. Passed through 151, the third half-wave plate 152 is changed to P polarized light. The phase-conjugated wave changed to P-polarized light is reflected by the third reflection mirror 153 and passes through the third lens 154 to be incident on the storage medium 170 (S130). At this time, the phase conjugate wave used as the reference light for reproduction is coaxial with the recording reference light and has the opposite direction of travel.

Subsequently, the P-polarized regenerated light reproduced in the storage medium 170 by the phase-conjugated wave is inverse Fourier transformed by the object lens 127, and is changed into S-polarized light while passing through the first half-wave plate 126. The light information is detected by the detector 160 by being reflected by the light splitter 123 (S140).

7 is an exemplary view showing a path in which the reference light and the phase conjugate wave reflected by the rotation mirror of the optical information processing apparatus of the present invention are incident on the storage medium.

)의 각으로 입사시키면 반사되는 기록용 기준광(R1)은 회전미러(131)에 입사된 각과 동일한 각(

')으로 반사되어 제 1렌즈(132)로 진행하게 된다. 이때 회전미러(131)의 각도를 조절하면 회전미러(131)에 의해 반사되는 기록용 기준광(R1)의 반사각이 달라지면서 저장매체(170)에 다양한 각도의 기준광을 제공할 수 있기 때문에 각도 다중화 방법으로 광정보를 기록할 수 있다. As shown in FIG. 7, the rotating mirror 131 may be used to use the reference light R as the recording reference light R1 used for recording optical information.

The recording reference light R1 reflected when incident at an angle of) is the same angle as the angle incident on the rotating mirror 131.

') Is reflected to the first lens 132. In this case, when the angle of the rotating mirror 131 is adjusted, the reflection angle of the recording reference light R1 reflected by the rotating mirror 131 may be changed, and thus the reference light having various angles may be provided to the storage medium 170. Optical information can be recorded.

)와 회전미러(131)에 입사되는 기준광(R)과 직각을 이루는 직선방향(R0)을 중심으로 회전미러(131)에서 반사되는 재생용 기준광(R2)의 각도(

')가 대칭되도록 회전미러(131)의 각도를 조절하면 재생용 기준광(R2)은 기록용 기준광(R1)의 위상공액파로 형성된다. In addition, in order to use the reference light R as the reproduction reference light R2 which is the sanitary conjugate wave of the recording reference light R1, the angle of the rotation mirror 131 must be set. At this time, the angle of the recording reference light R1 reflected from the rotation mirror 131 about the straight line R0 perpendicular to the linear direction in which the reference light R is incident on the rotation mirror 131 (

) And the angle of the reproduction reference light R2 reflected from the rotation mirror 131 about the linear direction R0 perpendicular to the reference light R incident on the rotation mirror 131 (

When the angle of the rotation mirror 131 is adjusted to be symmetrical, the reproduction reference light R2 is formed as a phase conjugate wave of the recording reference light R1.

In this case, the focal lengths of the first lens 132 and the second lens 143 and the focal lengths of the first lens 142 and the third lens 154 are the same, and the second lens 143 and the storage medium 170 are the same. ) And the reflecting member and the lens are arranged such that the focal lengths of the third lens 154 and the storage medium 170 coincide with each other, thereby controlling only the rotation mirror 131 to adjust the path of the reference light for recording and the path of the phase conjugate wave. have.

The reproduction light reproduced by the phase-conjugated wave proceeds along the path of the signal light during recording, and accurately cancels the phase change received by the signal part by part so that it is equal to the phase of the signal light at the same point on the path. Gets very good. In addition, since the phase conjugate wave can be incident on the storage medium 170 by adjusting only the angle of the rotating mirror 131, the reproducing reference light R2 can be easily replaced with the recording reference light R1 without using a plurality of reflecting members. It can form a phase conjugate wave.

8 is a block diagram showing an optical information processing apparatus according to another embodiment of the present invention.

As shown in FIG. 8, the optical information processing apparatus records a light source 200, a first light splitter 210 that separates light into signal light and reference light, a signal light optical system 220 that provides a path to signal light, and a reference light for reproduction. A reference light optical system 230 formed of a phase-conjugated wave of the reference light used for recording, dividing a path between the reference light for recording and the reference light for reproduction, and a reference light optical system 240 for guiding the recording reference light to the storage medium 270, and reproduction. The reproduction reference light optical system 250 for guiding the reference light for storage to the storage medium 270, and a detector 260 for detecting the optical information reproduced from the storage medium 270.

The signal light optical system 220 is positioned in the path of the signal light separated from the light by the first light splitter 210. The signal light optical system 220 reflects the signal light shutter 221 for passing and blocking the signal light, the first and second reflection mirrors 222 and 223 for guiding the signal light to the optical modulator 226 according to polarization. And a second quarter splitter 224 for changing the polarization of the signal light reflected by the second splitter 224, and a light modulator 226 for loading data into the signal light. A first half wave plate 227 for changing the polarization of the signal light passing through the first quarter wave plate 225, and an objective lens 228 for Fourier transforming the signal light.

On the other hand, the reference light optical system 230 is positioned in the path of the reference light separated by the first light splitter 210. The reference light optical system 230 reflects the recording reference light used for recording the optical information, and adjusts the angle to form a rotational mirror 231 to form a phase conjugate wave of the recording reference light used for recording the reference reference light used for reproducing the optical information And a first lens 232 for guiding the reference light reflected from the rotation mirror 231, and a third light splitter 233 for dividing a path between the recording reference light and the reproduction reference light.

The recording reference light optical system 240 is positioned in the path of the recording reference light separated by the third light splitter 233. The recording reference light optical system 240 polarizes the recording reference light shutter 241 for blocking and passing the recording reference light passed through the third light splitter 233 and the recording reference light passing through the recording reference light shutter 241. A third reflecting mirror 243, a fourth reflecting mirror 244, and two lenses for guiding the recording reference light transmitted through the second half wave plate 242 and the second half wave plate 242 to the storage medium 270. (245).

The reproduction reference light optical system 250 is positioned in the path of the reproduction reference light separated by the third light splitter 233. The reproduction reference light optical system 250 includes a reproduction reference light shutter 251 for passing and blocking the reproduction reference light, a fourth light splitter 252 for reflecting the reproduction reference light, and a fourth light splitter 252 for reproduction. The second and second quarter wave plates 253 and 253 which change the polarization of the reference light for reproduction reflected by the fifth reflection mirror 254 and pass through the second quarter wave plate 253 And a third lens 255 for guiding the reproduction reference light to the storage medium 270.

As such, in the case of an incident environment where the focal lengths of the first lens 232 and the second lens 245 and the focal lengths of the first lens 232 and the third lens 255 coincide with each other, the high reproduction efficiency is achieved even if the arrangement of the configuration is different. Can be obtained.

1 is a block diagram showing an optical information processing apparatus according to an embodiment of the present invention.

2 is a view showing an operation of recording optical information in the optical information processing apparatus according to the embodiment of the present invention.

3 is a diagram illustrating an operation of reproducing optical information of the optical information processing apparatus according to the embodiment of the present invention.

4 is a flowchart illustrating an optical information processing method according to an embodiment of the present invention.

5 is a flowchart showing an optical information recording method according to an embodiment of the present invention.

6 is a flowchart illustrating a method of reproducing optical information according to an embodiment of the present invention.

7 is an exemplary view showing a path in which the reference light and the phase conjugate wave reflected by the rotation mirror of the optical information processing apparatus of the present invention are incident on the storage medium.

8 is a block diagram showing an optical information processing apparatus according to another embodiment of the present invention.

Claims (16)

Light source; A light splitter separating the light emitted from the light source into signal light and reference light; A signal light optical system for loading data into the signal light and guiding the signal light loaded with the data to a storage medium; A reference light optical system for dividing the reference light into a recording reference light and a reproduction reference light, and setting an angle so that the reproduction reference light becomes a phase conjugate wave of the recording reference light to divide the path between the recording reference light and the reproduction reference light; A recording reference light optical system for guiding the recording reference light to the storage medium; A reference light optical system for reproducing the reference light for reproduction to the storage medium; And a detector for detecting optical information reproduced from the storage medium by the reproduction reference light. The optical system of claim 1, wherein the signal optical system A signal light shutter for passing the signal light when the optical information is recorded; A light splitter that separates the signal light reflected by the reflection mirror according to polarization; An optical modulator for loading data into the signal light separated from the optical splitter; A quarter wave plate for changing the polarization of the signal light on which the data is loaded; A half-wave plate for changing the polarization of the signal light whose polarization is changed by the quarter wave plate; And an objective lens for Fourier transforming the signal light whose polarization is changed by the half-wave plate. The optical system of claim 1, wherein the reference light optical system A rotation mirror which reflects the reference light and uses the reference light as a recording reference light and sets an angle so that the reproduction reference light becomes a phase conjugate wave of the recording reference light; And a light splitter for separating the recording reference light and the reproduction reference light reflected by the rotation mirror. 4. The phase-conjugated wave of claim 3, wherein the phase conjugate wave is reflected at an angle symmetric to a reflection angle of the recording reference light reflected from the rotation mirror about a linear direction perpendicular to the angle at which the recording reference light is incident on the rotation mirror. Optical information processing apparatus, characterized in that formed. 4. The optical system of claim 3, wherein the recording reference optical system A recording reference light shutter for passing the recording reference light when the optical information is recorded; And a half-wave plate for changing the polarization of the recording reference light passing through the recording reference light shutter. The optical system for reproducing the reference light of claim 3, wherein A reproduction reference light shutter which passes the reproduction reference light when the optical information is reproduced; And a half-wave plate for changing the polarization of the reproduction reference light passing through the reproduction reference light shutter. The optical information processing apparatus according to claim 1, wherein the optical information is a holographic interference fringe recorded in multiplex, and the multiple recording of the optical information is performed by adjusting the angle of the rotating mirror. Separating the light provided from the light source into signal light and reference light; Loading data onto the signal light and entering the storage medium, and entering the reference light into the storage medium and recording optical information; Setting an angle of the rotating mirror to form a phase conjugate wave of the reference light; Irradiating the phase-conjugated wave formed by the rotating mirror to the storage medium on which the optical information is recorded; Detecting the reproduced light reproduced by the phase conjugate wave. 10. The method of claim 8, wherein the phase conjugate wave is formed by reflecting the reference light at an angle symmetrical with a reflection angle reflected from the rotation mirror about a linear direction perpendicular to the angle at which the reference light is incident on the rotation mirror. Optical information processing method characterized in that. The optical information processing method according to claim 8, wherein the reference light incident on the storage medium and the phase conjugate wave incident on the storage medium are coaxial and propagate to the storage medium in opposite directions. Separating the light provided from the light source into signal light and reference light; Setting a rotation mirror at an arbitrary angle to use the reference light as a recording reference light for optical information recording; The reference light is reflected by the rotation mirror, and And loading data into the signal light and entering the storage medium, and recording the optical information by entering the recording reference light into the storage medium. 12. The optical information processing method according to claim 11, wherein the optical information is multiplely recorded on the storage medium by adjusting the angle of the rotating mirror. Setting an angle of the rotation mirror such that the reproduction reference light is formed as a phase conjugate wave of the recording reference light used when recording the optical information; Irradiating the phase conjugate wave formed by the rotating mirror to a storage medium on which the optical information is recorded; Detecting reproduction light reproduced by the reproduction reference light. The phase-conjugated wave of claim 13, wherein the phase conjugate wave is reflected at an angle that is symmetrical with a reflection angle of the recording reference light reflected from the rotation mirror about a straight line direction perpendicular to the angle at which the recording reference light is incident on the rotation mirror. Optical information processing method characterized in that it is formed. 15. The optical recording medium of claim 13, wherein the reproduction reference light incident on the storage medium is coaxial with the recording reference light irradiated on the storage medium when the optical information is recorded and is incident on the storage medium in opposite directions. Information processing method. The optical information processing method according to claim 13, wherein the reproduction of the optical information is reproduced in multiple times in the storage medium by adjusting the angle of the rotating mirror.

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