KR20080080751A - Apparatus and method for reading optical information - Google Patents

Abstract

An apparatus and a method for reproducing optical information are provided to improve the reproduction efficiency of optical information by aligning an optical information storage medium for reproducing a reproduction beam. An apparatus for reproducing optical information comprises an optical system(100), a control beam detecting part(200), a controller(500), and an optical information detecting part(400). The optical system projects a first light to an optical information storage medium with a recording area for aligning the optical information storage medium, and a second light through a path different from that of the first light. The control beam detecting part detects a tilting control beam and a shift control beam generated by the first beam and the second beam entering the recording area. The controller judges the tilting and shift condition of the optical information storage medium through the tilting control beam the shift control beam. The optical information detecting part detects a reproducing beam reproduced by incidence of the reference beam for reproduction to the optical information storage medium.

Description

Optical information reproducing apparatus and optical information reproducing method {Apparatus and Method for reading optical information}

1 is a configuration diagram briefly showing an optical information reproducing apparatus according to an embodiment of the present invention.

2 is a flowchart illustrating a method of reproducing optical information through tilting control according to an exemplary embodiment of the present invention.

3 is a flowchart illustrating a method of reproducing optical information through shift control according to an exemplary embodiment of the present invention.

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

10: optical information storage medium

100: optical system

200: control light detector

300: alignment unit

400: optical information detection unit

500: control unit

The present invention relates to an optical information reproducing apparatus and an optical information reproducing method, and more particularly, to store an alignment recording area which is an alignment criterion of an optical information storage medium in an optical information storage medium, and when reproducing optical information, An optical information reproducing apparatus and an optical information reproducing method for detecting a control light reproduced from the same and aligning an optical information storage medium.

In general, optical information storage devices that store optical information include compact discs (CDs), digital versatile discs (DVDs), high definition DVDs (HD-DVDs), and blu-ray discs (BDs). Blue-ray Disc).

Recently, with the rapid development of the information and computer industry, there is an increasing demand for a next generation storage device capable of satisfying high capacity storage capacity and high speed input / output of data.

One of the systems that are attracting the most attention in accordance with these demands is an optical information processing apparatus using a principle of volume holography, that is, a holographic optical information processing apparatus.

The holographic optical information processing apparatus is a system conceived from the principle that when two lights having different incidence angles intersect at a predetermined position of a light sensitive photosensitive medium, an interference pattern generated by the interference of the two lights is recorded on the photosensitive medium. .

That is, when a signal beam including data information and a reference beam irradiated from an angle different from the signal beam cross each other at a predetermined position of an optical information storage medium that is a photosensitive medium, the interference pattern generated at this time is stored in the optical information. Recorded on the medium. In addition, when the data information is reproduced, only the reference light is irradiated to the recorded interference pattern, and original data is restored by using a diffraction image generated by the interference pattern.

The holographic optical information processing apparatus may record data by three-dimensionally superimposing data at the same position of the optical information recording medium by using various multiplexing techniques. This superimposition recording can dramatically increase the capacity stored in a limited area, thereby realizing an ultra large storage system.

In this case, the multiplexing technique may include angle multiplexing, phase-code multiplexing, wavelength multiplexing, fractal multiplexing, shift multiplexing, and ferrotropic multiplexing. Peristrophic Multiplexing, Polytopic Multiplexing, and the like.

As described above, in order to reproduce the optical information from the recording area recorded on the optical information storage medium having excellent recording density, the incident angle of the reference light incident upon the optical information recording and the incident position of the signal light must be restored.

However, when the optical information storage medium is mounted on the optical information processing device for reproducing the optical information, the optical information storage medium may tilt and change depending on the optical information processing device. This causes a problem that the incidence angle of the reference light and the incidence position of the signal light recorded in the recording area are not properly restored, thereby reducing the optical information reproduction efficiency.

Therefore, there is a need for an alignment technology of an optical information storage medium mounted in an optical information processing apparatus.

SUMMARY OF THE INVENTION In order to solve the above problems, an object of the present invention is to provide an optical information reproducing apparatus and an optical information reproducing method capable of determining a tilting state and a shift state of an optical information storage medium.

In order to achieve the above object, an optical information reproducing apparatus according to an embodiment of the present invention injects a first light into an optical information storage medium having an alignment recording area for aligning the optical information storage medium, and an incident path of the first light. An optical system for injecting a second light in a different path from the optical path; a control light detector for detecting a tilting control light and a shifting control light generated by the first light and the second light incident on the alignment recording region; And a control unit for determining a tilting state and a shift state of the optical information storage medium from the shift control light, and an optical information detection unit detecting a reproduction light to be reproduced by injecting a reproduction reference light into the optical information storage medium.

The first light may be coaxial with a reference light incident upon optical information recording, and may be incident on the optical information storage medium in a direction opposite to the incident direction of the reference light.

The second light may be incident on the optical information storage medium along the incident path of the signal light incident upon the optical information recording.

The controller determines the tilting state and the shift state of the optical information storage medium to be normal when the light intensity of the tilting control light and the shift control light is detected to the maximum by scanning the light intensities of the tilting control light and the shift control light. can do.

The reproduction reference light may have a coaxial axis with the reference light incident upon the recording of the optical information, and may be incident on the optical information storage medium in a direction opposite to the incident direction of the reference light incident on the optical information storage medium.

An optical information reproducing apparatus according to another embodiment of the present invention is an optical information storage medium provided with an alignment recording area for aligning an optical information storage medium, and has an optical axis coaxial with a reference light incident on the optical information storage medium when optical information recording is performed. The first light is incident on the optical information storage medium in a direction opposite to the direction of incidence of the reference light incident on the optical information storage medium, and the first light is incident on the optical information storage medium along the incident path of the signal light incident upon optical information recording. An optical system for injecting light, a tilting control light generated by the first light, and a control light detector for detecting a shift control light generated by the second light, a tilting state of the optical information storage medium from the control light, and A control unit for determining a shift state and an optical information detection unit for detecting a reproduction light to be reproduced by injecting a reproduction reference light into the optical information storage medium. The.

The controller may determine the shift state of the optical information storage medium to be normal when the light intensity of the tilting control light and the shift control light is detected to the maximum by scanning the light intensity of the tilting control light and the shift control light. have.

An optical information reproducing method according to another embodiment of the present invention comprises injecting at least one of the first light and the second light into an alignment recording area for aligning the optical information storage medium, the first light and the second light. Detecting a tilting control light and a shift control light generated by the light; determining a tilting state and a shift state of the optical information storage medium by the light intensities of the tilting control light and the shift control light; and the optical information storage medium. And detecting the reproduction light to be reproduced by injecting the reference light for reproduction.

The first light may be coaxial with the reference light incident upon the optical information recording, and may be incident on the optical information storage medium in a direction opposite to the incident direction of the reference light incident on the optical information storage medium.

The second light may be incident on the optical information storage medium along an incident path of the signal light incident upon the optical information recording.

The determining of the tilting state and the shift state of the optical information storage medium may include scanning the light intensity of the tilting control light and the shift control light to detect the maximum light intensity of the tilting control light and the shift control light. The tilting state and the shift state of the information storage medium can be determined to be normal.

The detecting of the reproduction light may include the reproduction reference light coaxial with the reference light incident upon the recording of the optical information, and move to the optical information storage medium in a direction opposite to the incident direction of the reference light incident on the optical information storage medium. Can be incident.

Hereinafter, an optical information processing apparatus, an optical information reproducing apparatus, an optical information storage medium, and an optical information reproducing method will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram briefly showing an optical information reproducing apparatus according to an embodiment of the present invention.

1, an optical information reproducing apparatus according to an exemplary embodiment of the present invention includes an optical system 100, a control light detector 200, an alignment unit 300, an optical information detector 400, and a controller 500. .

The optical system 100 stores the recording area by crossing two lights having different incidence angles in the optical information storage medium 10. The recording area may be divided into an optical information recording area having optical information and an alignment recording area which is an alignment standard of the optical information storage medium.

The optical system 100 enters one of the reference light R and the signal light S into the alignment recording area recorded on the optical information storage medium 10 to reproduce the control light Pa, and the optical information storage medium 10 The reference light R is made incident on the optical information recording area recorded at &quot;

 The optical system 100 includes a light source 110, a recording reference light optical system 150, a reproduction reference light optical system 170, and a signal light optical system 190.

The light source 110 emits light. Light emitted from the light source 110 may have P-polarized light and S-polarized light.

The first polarized light splitter 130 is provided on the path of the light emitted from the light source 110. The first polarized light splitter 130 transmits light of P-polarized light and reflects light of S-polarized light among the light emitted from the light source 110. The P-polarized light transmitted by the first polarized light splitter 130 is used as the reference light R, and the light of the S-polarized light reflected by the first polarized light splitter 130 is used as the signal light S.

The first light splitter 131 is provided on a path of the reference light R transmitted by the first polarized light splitter 130. The first light splitter 131 reflects a part of the reference light R to the recording reference light optical system 150, and transmits the remaining light to the reproduction reference light optical system 170.

The first shutter 140 is provided on the path of the reference light R reflected by the first light splitter 131. The first shutter 140 interrupts the reference light R traveling to the recording reference light optical system 150. The first shutter 140 is opened so that the reference light R is incident upon storing the optical information recording area and the alignment recording area. On the other hand, when the signal light S and the reference light R are incident to the alignment recording area to reproduce the control light Pa, and the reference light R is incident to the optical information recording area to reproduce the reproduction light Pb, the reference light is received. Block the progress of (R).

The recording reference light optical system 150 is provided on the path of the reference light R that proceeds when the first shutter 140 is opened. When storing the optical information recording area and the alignment recording area, the recording reference light optical system 150 enters the reference light R into the optical information storage medium 10 so as to intersect the signal light S in the optical information storage medium 10.

The recording reference optical system 150 includes a first rotating mirror 151 and a first λ / 4 wave plate 152.

The first rotating mirror 151 is provided on the path of the reference light R passing through the first shutter 140. The first rotating mirror 151 multiplexes the angle of the reference light R incident to the optical information storage medium 10. The angular multiplexed reference light R intersects the signal light S in the optical information storage medium 10 so that the recording area can be superimposed and stored. The first rotating mirror 151 may be a galvano mirror.

The first λ / 4 wave plate 152 is provided on the path of the reference light R incident by the first rotation mirror 151. The first λ / 4 wave plate 152 converts the reference light R of P-polarized light incident to the optical information storage medium 10 into circularly polarized light and enters the optical information storage medium 10.

Meanwhile, the second shutter 160 is provided on the path of the reference light R transmitted by the first light splitter 131. The second shutter 160 intercepts the reference light R which proceeds to the reproduction reference light optical system 170. The second shutter 160 is opened to allow the reference light R to enter the optical information recording area and the alignment recording area so as to reproduce the control light Pa and the reproduction light Pb. On the other hand, the progress of the reference light R is blocked when storing the optical information recording area and the alignment recording area and when the signal light S is incident on the alignment recording area in order to reproduce the control light Pa.

The second light splitter 133 is provided on a path of the reference light R that proceeds when the second shutter 160 is opened. The second light splitter 133 reflects a part of the reference light R that has passed through the second shutter 160, and transmits the remaining light.

The reproduction reference light optical system 170 is provided on the path of the reference light R passing through the second light splitter 133. The reproduction reference light optical system 170 enters the reference light R into the optical information storage medium 10 so that the reference light R has an angle of incidence when storing the optical information recording area and the alignment recording area when the reproduction light Pb and the control light Pa are reproduced. Let's do it.

The reproduction reference optical system 170 includes a second rotation mirror 171 and a second λ / 4 wave plate 172.

The second rotating mirror 171 is provided on the path of the reference light R passing through the second shutter 160. The second rotating mirror 171 adjusts an angle of incidence of the reference light R incident to the optical information storage medium 10. The second rotating mirror 171 adjusts the angle of incidence of the reference light R in order to reproduce the optical information of the recording area that is angularly multiplexed on the optical information storage medium 10 and overwritten. The second rotating mirror 171 may be a galvano mirror.

Here, the incident direction of the reference light R incident by the second rotating mirror 171 may be incident in a direction opposite to the incident direction of the reference light R incident from the recording reference light optical system 150.

The second λ / 4 wave plate 172 is provided on a path of the reference light R reflected by the second rotation mirror 171. The second λ / 4 wave plate 172 converts the reference light R of P-polarized light incident on the optical information storage medium 10 into circularly polarized light and enters the optical information storage medium 10.

Meanwhile, the third shutter 180 is provided on the path of the signal light S reflected by the first polarized light splitter 120. The third shutter 180 interrupts the progress of the signal light S incident on the signal light optical system 190. The third shutter 180 is opened when the optical information recording area and the alignment recording area are stored, and when the signal light S enters the alignment recording area to reproduce the control light Pa. On the other hand, in order to reproduce the control light Pa and the reproduction light Pb, the progress of the signal light S is blocked when the reference light R is incident into the optical information recording area and the alignment recording area.

When storing the optical information recording area and the alignment recording area, the signal light optical system 190 injects the signal light S into the optical information storage medium 10 so as to intersect the reference light R in the optical information storage medium 10. In addition, the signal light optical system 190 causes the signal light S to enter the alignment recording area when the control light Pa is reproduced.

The signal light optical system 190 includes a spatial light modulator 191, a second polarized light splitter 192, a Fourier transform lens 193, and a third λ / 4 wave plate 194.

The spatial light modulator 191 is provided on a path of the signal light S passing through the third shutter 180. The spatial light modulator 191 modulates the signal light S and enters the optical information storage medium 10. The modulation of the signal light S is performed by loading a data page divided into on / off pixels into the signal light S. FIG.

Here, the spatial light modulator 191 may load a data page distinguished from the signal light S incident to the optical information recording area onto the signal light S incident to the alignment recording area. That is, the spatial light modulator 191 may load a data page made of pixels on the signal light S incident to the alignment recording area. This makes the light intensity of the control light Pa reproduced in the alignment recording area larger than the light intensity of the reproduction light Pb reproduced in the optical information recording area, so that the alignment information is recorded from the optical information recording area in the optical information storage medium 10. The area is for easy detection.

The second polarized light splitter 192 is provided on the path of the signal light S modulated by the spatial light modulator 191. The second polarized light splitter 192 transmits the S-polarized signal light S and enters the Fourier transform lens 193.

The Fourier transform lens 193 is provided on the path of the signal light S transmitted by the second polarized light splitter 192. The Fourier transform lens 193 performs Fourier transform on the signal light S and enters the optical information storage medium 10.

The third λ / 4 wave plate 194 is provided between the optical information storage medium 10 and the Fourier transform lens 193. The third λ / 4 wave plate 194 changes the polarization of the Fourier transformed signal light S from S-polarized light to circularly polarized light and enters the optical information storage medium 10.

The control light detector 200 is provided to detect one of the reference light R and the signal light S by the optical information storage medium 10 and detect the reproduced control light Pa.

The control light detector 200 includes a first control light detector 220 and a second control light detector 240.

When the reference light R is incident on the optical information storage medium 10 through the reproduction reference light optical system 170 to reproduce the control light Pa, the control light Pa is reproduced by the signal light optical system 190. The control light Pa reproduced by the signal light optical system 190 is changed to the control light Pa of the S-polarized light through the third λ / 4 wave plate 194 and reflected by the second polarized light splitter 192.

Here, the optical system 100 includes a third light splitter 135 on a path of light reflected by the second polarized light splitter 192. The third light splitter 135 transmits a part of the control light Pa reflected by the second polarized light splitter 192 and reflects the rest.

The first control light detector 220 is provided on a path of the control light Pa reflected by the third light splitter 135 to detect the control light Pa. In this case, the control light Pa detected by the first control light detector 220 becomes a tilting control light capable of determining a tilting state of the optical information storage medium 10.

Meanwhile, when the signal light S is incident on the optical information storage medium 10 through the signal light optical system 190 to reproduce the control light Pa, the control light Pa is reproduced by the reproduction reference light optical system 100. The control light Pa reproduced by the reproduction reference light optical system 170 is changed to the control light Pa of P-polarized light through the second λ / 4 wave plate 172 and passes through the reproduction reference light optical system 170.

Part of the control light Pa passing through the reproduction reference light optical system 170 is transmitted by the second light splitter 133, and the rest is reflected.

The second control light detector 240 is provided on a path of the control light Pa reflected by the second light splitter 133 and detects the control light Pa. In this case, the control light Pa detected by the second control light detector 240 becomes a shift control light for determining the shift state of the optical information storage medium 10.

The controller 500 determines the position state of the optical information storage medium 10 from the control light Pa obtained from the first control light detector 220 and the second control light detector 240. That is, the tilting state and the shift state of the optical information storage medium 10 are determined and transmitted to the alignment unit 300 to align the optical information storage medium 10.

Here, as described above, the alignment recording area is recorded as a data page made up of pixels turned on by the spatial light modulator 191 so that the light intensity of the control light Pa is detected the largest. Accordingly, the control unit 500 controls the optical information storage medium 10 to be aligned according to the incident position of the signal light S and the incident angle of the reference light R where the light intensity of the control light Pa is detected to be greatest.

The optical information detector 400 is reflected by the second polarized light splitter 192 and provided on a path of the reproduced light Pb passing through the third light splitter 135 to detect the reproduced light Pb.

2 is a flowchart illustrating a method of reproducing optical information through tilting control according to an embodiment of the present invention.

Referring to FIG. 2, light is emitted from the light source 110. The light emitted from the light source 110 is split into the reference light R and the signal light S by the first polarized light splitter 120. The divided reference light R passes through the first polarized light splitter 120, and the divided signal light S is reflected by the first polarized light splitter 120. In this case, the signal light S reflected by the first polarized light splitter 120 is blocked by the third shutter 180.

The reference light R transmitted through the first polarized light splitter 120 is partially transmitted by the first light splitter 131, and the other is reflected. The reference light R reflected by the first light splitter 131 is blocked by the first shutter 140, and the reference light R passing through the first light splitter 131 is incident to the reproduction reference light optical system 170. . The reference light R incident to the reproduction reference light optical system 170 is adjusted by the second rotation mirror 171 to be incident on the optical information storage medium 10 (S31).

The optical information storage medium 10 records an alignment recording area which is separated from the optical information recording area. That is, the light intensity of the control light Pa reproduced in the alignment recording area is greater than that of the reproduction light Pb reproduced in the optical information recording area. Therefore, the recording area in which the reference light R is incident on the optical information storage medium 10 and the light intensity is detected is the alignment recording area.

When the alignment recording area is detected in this manner, the reference light R is incident on the alignment recording area. The control light Pa reproduced by the reference light R is changed to S-polarized light through the third λ / 4 wave plate 194 and proceeds to the second polarized light splitter 192. The control light Pa of the S-polarized light is reflected by the second polarized light splitter 192 and proceeds to the third light splitter 135. In the third light splitter 135, the control light Pa is partially transmitted, and the others are reflected. The control light Pa reflected by the third light splitter 135 is detected by the first control light detector 220 (S33).

In this case, the controller 500 analyzes the light intensity of the control light Pa to determine the tilting state of the optical information storage medium 10 (S35). That is, the control unit 500 adjusts the control signal for adjusting the inclination of the optical information storage medium 10 so that the light intensity of the control light Pa corresponds to the incident angle of the reference light R, which is detected with the greatest intensity. To send. The alignment unit 300 adjusts the inclination of the optical information storage medium 10 according to the control signal.

Subsequently, the reproduction light Pb that is inputted and reproduced by the reference light R into the optical information recording area is changed to S-polarized light through the third λ / 4 wave plate 194 to the second polarized light splitter 192. Proceed. The regenerated light Pb of the S-polarized light is reflected by the second polarized light splitter 192 and proceeds to the third light splitter 135. In the third light splitter 135, a part of the regenerated light Pb is reflected and the others are transmitted. The reproduction light Pb transmitted by the third light splitter 135 is detected by the optical information detector 400 (S37).

3 is a flowchart illustrating a method of reproducing optical information through shift control according to an exemplary embodiment of the present invention.

Referring to FIG. 3, light is emitted from the light source 110. The light emitted from the light source 110 is split into the reference light R and the signal light S by the first polarized light splitter 120. The divided reference light R passes through the first polarized light splitter 120, and the divided signal light S is reflected by the first polarized light splitter 120. In this case, the reference light R transmitted through the first polarized light splitter 120 is blocked by the first shutter 140 and the second shutter 160.

The signal light S reflected by the first polarized light splitter 120 is incident to the spatial light modulator 191. The spatial light modulator 191 modulates the signal light S under the same conditions as the signal light S modulated at the time of recording the alignment recording area. The signal light S modulated by the spatial light modulator 191 is Fourier transformed by the Fourier lens 193 and is incident on the optical information storage medium 10 (S51).

The optical information storage medium 10 records an alignment recording area which is separated from the optical information recording area. That is, the light intensity of the control light Pa reproduced in the alignment recording area is greater than that of the reproduction light Pb reproduced in the optical information recording area. Therefore, the recording area in which the signal light S is incident on the optical information storage medium 10 and the light intensity is detected is the aligned recording area.

When the alignment recording area is detected in this manner, the signal light S is incident on the alignment recording area. The control light Pa reproduced by the signal light S passes through the reproduction reference light optical system 170 to the second light splitter 133. In the second light splitter 133, the control light Pa is partially transmitted and the other is reflected. The control light Pa reflected by the second light splitter 133 is detected by the second control light detector 240 (S53).

In this case, the controller 500 determines the shift state of the optical information storage medium 10 by analyzing the light intensity of the control light Pa (S55). That is, the controller 500 positions the control signal for adjusting the position of the optical information storage medium 10 so that the alignment recording area is positioned at the incidence position of the signal light S in which the light intensity of the control light Pa is detected to be greatest. Transmit to the alignment unit 300. The alignment unit 300 adjusts the position of the optical information storage medium 10 according to the control signal.

Subsequently, the reproduction light Pb that is inputted and reproduced by the reference light R into the optical information recording area is changed to S-polarized light through the third λ / 4 wave plate 194 to the second polarized light splitter 192. Proceed. The regenerated light Pb of the S-polarized light is reflected by the second polarized light splitter 192 and proceeds to the third light splitter 135. In the third light splitter 135, a part of the regenerated light Pb is reflected and the others are transmitted. The reproduction light Pb transmitted by the third light splitter 135 is detected by the optical information detector 400 (S57).

As described above, the optical information reproducing apparatus according to the embodiment of the present invention detects the control light (Pa) reproduced from the alignment recording area, analyzes the light intensity of the detected control light (Pa) and the optical information storage medium Tilt and shift of (10) can be adjusted.

Here, the tilting and shift adjustment of the optical information storage medium by the optical information reproducing apparatus according to the embodiment of the present invention may be performed at the same time, only one of the tilting and shift adjustment may be performed. When the tilting adjustment and the shift adjustment of the optical information storage medium are performed at the same time, the purpose of performing the alignment of the optical information storage medium may be achieved even if any one of the tilting adjustment and the shift adjustment is performed first.

As described above, the optical information reproducing apparatus and the optical information reproducing method according to the present invention align the optical information storage media mounted on the optical information processing apparatus and reproduce the reproduced light, thereby increasing the optical information reproducing efficiency. There is.

Claims (12)

An optical system for injecting first light into an optical information storage medium having an alignment recording area for aligning the optical information storage medium, and for injecting the second light through a path different from an incident path of the first light; A control light detector for detecting a tilting control light and a shift control light generated by the first light and the second light incident on the alignment recording area; A controller configured to determine a tilting state and a shift state of the optical information storage medium from the tilting control light and the shift control light; And And an optical information detector for detecting reproduction light to be reproduced by injecting a reproduction reference light into the optical information storage medium. The optical information reproducing apparatus according to claim 1, wherein the first light is coaxial with a reference light incident upon optical information recording and is incident on the optical information storage medium in a direction opposite to the incident direction of the reference light. The optical information reproducing apparatus according to claim 1, wherein the second light is incident on the optical information storage medium along an incident path of signal light incident upon optical information recording. The tilting state of the optical information storage medium according to claim 1, wherein the control unit scans the light intensities of the tilting control light and the shift control light to detect the maximum light intensity of the tilting control light and the shift control light. The optical information reproducing apparatus characterized by determining the shift state to be normal. The optical information storage medium of claim 1, wherein the reproduction reference light has coaxiality with the reference light incident upon the optical information recording, and is incident on the optical information storage medium in a direction opposite to the incident direction of the reference light incident on the optical information storage medium. Optical information reproducing apparatus, characterized in that. An optical information storage medium having an alignment recording area for aligning an optical information storage medium, the optical information storage medium having a coaxial with a reference light incident on the optical information storage medium when optical information recording, and an incident direction of the reference light incident on the optical information storage medium. An optical system for injecting a first light into the optical information storage medium in a direction opposite to that of the optical information storage medium, and for injecting a second light into the optical information storage medium along an incident path of the signal light incident upon the optical information recording; A control light detector for detecting a tilting control light generated by the first light and a shift control light generated by the second light; A controller for determining a tilting state and a shift state of the optical information storage medium from the control light; And And an optical information detector for detecting reproduction light to be reproduced by injecting a reproduction reference light into the optical information storage medium. The optical control apparatus of claim 6, wherein the controller scans the light intensities of the tilting control light and the shift control light to detect a shift state of the optical information storage medium when the light intensities of the tilting control light and the shift control light are detected to the maximum. An optical information reproducing apparatus, characterized in that it is determined to be normal. Injecting at least one of the first light and the second light into an alignment recording area for alignment of the optical information storage medium; Detecting a tilting control light and a shift control light generated by the first light and the second light; Determining a tilting state and a shift state of the optical information storage medium based on the light intensities of the tilting control light and the shift control light; And And detecting a reproduction light to be reproduced by injecting a reproduction reference light into the optical information storage medium. 10. The optical information storage medium of claim 8, wherein the first light has coaxiality with the reference light incident upon the optical information recording, and is incident on the optical information storage medium in a direction opposite to the incident direction of the reference light incident on the optical information storage medium. Optical information reproduction method characterized in that. The optical information reproducing method according to claim 8, wherein the second light is incident on the optical information storage medium along an incident path of signal light incident upon the optical information recording. The method of claim 8, wherein the determining of the tilting state and the shifting state of the optical information storage medium comprises: scanning the light intensity of the tilting control light and the shift control light to maximize the light intensity of the tilting control light and the shift control light. And when detected, determine the tilting state and the shifting state of the optical information storage medium as normal. 10. The method of claim 8, wherein the detecting of the reproduction light comprises coaxial with the reference light incident upon the recording of the optical information, and in a direction opposite to the incident direction of the reference light incident on the optical information storage medium. And entering the optical information storage medium.

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