KR20000042554A - Apparatus for controlling optical arrangement of digital holographic data storing system - Google Patents

Abstract

PURPOSE: An apparatus for controlling an arrangement of an optical system is provided to precisely arrange and control an optical system using an interferometer to match a pixel of SLM(Spatial Light Modulator) and CCD(Charge Coupled Device). CONSTITUTION: An apparatus for controlling an arrangement includes a first beam splitter(16), a storing material(170), a mirror(200), a beam magnifier(210), a second beam splitter(220), a first CCD(230), a precision stage(270), a second CCD(280), a controlling unit(250), and a precision stage driving unit(260). The first beam splitter splits an illuminated standard beam. The storing material restores an interference pattern recorded by the standard beam and emits a revival beam. The mirror changes the direction of the standard beam. The beam magnifier magnifies the standard beam reflected from the mirror. The second beam splitter separates and outputs the standard beam passed through the beam magnifier and the revival beam emitted from the storing material into first and second interference patterns. The first CCD changes the first interference pattern into an electrical signal and outputs as an output data. The precision stage is positioned under the fist CCD, fixes and arranges the first CCD. The second CCD changes the second interference pattern into an electrical signal and outputs as an output data. The controlling unit outputs a control signal to control the precision stage. The precision stage driving unit controls the precision stage to move the first CCD.

Description

OPTICAL INSTRUMENT ARRAY CONTROL APPARATUS FOR DIGITAL HOLOGRAPHIC DATA STORAGE SYSTEM

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical system alignment adjusting device for adjusting the alignment of an optical system in a digital holographic data storage system. In particular, the present invention relates to a simple and precise alignment of an optical system using an interferometer. An optical system alignment adjustment device.

In general, digital holographic data storage systems aim to record object light from an object and subsequently reproduce it.

Holographic data recording is achieved by recording the intensity and direction of the object light reflected from the object. The intensity and direction of the light of the object is composed of the interference between the object light and the reference light to form an interference fringe, and the interference fringe is formed in a cube, that is, a storage crystal, made of a material that responds to the intensity of the interference fringe. When the reference light is irradiated to the recorded interference fringe, the hologram, which is a three-dimensional image of the object, is reproduced.

At this time, the hologram data recorded in the storage crystal can be read only by the reference light used in the recording process, and the hologram data recorded in the storage crystal can not be read by the reference light having a different wavelength or phase from the reference light used in the recording process. Done.

By using this hologram property, it is possible to store a large amount of data in a small cube by recording a lot of hologram data in the same place of the storage material cube with different reference light.

As shown in FIG. 1, a general digital holographic data storage system is installed at a position corresponding to a coherent beam required for holography, that is, a light source 10 for generating a laser light, and a light source 10. 10. A beam splitter 20 which separates the aggregated light generated from the light into a reference beam and a signal beam, that is, an object beam, and is located on the optical path of the reference beam and converts the angle of the reference beam little by little. A rotating mirror 30 for changing the direction of the object light, a mirror 40 for changing the direction of the object light, and a plurality of pixels arranged on the optical path of the object light reflected from the mirror 40 and configured as input data, that is, in units of pages. Spatial light modulator (SLM) 50 for carrying the true data, the object light output from the spatial light modulator 50 and the reference light reflected from the rotating mirror 30 is located on the optical path crossing each otherThe optical path of the interference fringe generated when irradiating the reference light to the storage medium 60 and the storage medium 60 which records the interference fringe generated by the interference between the object light and the reference light and restores the interference fringe recorded by the irradiation of the reference light. Charge Coupled Device (CCD) 70 for converting the interference fringes, which are located on and stored in the storage medium 60 into original electrical signals, and the precision stage 80 to which the CCD 70 is fixed. )

The operation of the general digital holographic data storage system configured as described above will be described.

The coherent light irradiated from the light source 10 is divided into the reference light and the object light in the optical separator 20.

In this case, the object light is inputted to the spatial light modulator 50 and modulated by the mirror 40 in a 90 ° direction. That is, the object light is incident on the storage medium 60 after the data input from the spatial light modulator 50 is modulated in units of one page of binary data of light and shade of actual pixels.

In addition, the reference light is incident on the storage medium 60 by changing the angle by the rotating mirror 30. That is, the reference light which slightly changes the angle of the rotating mirror 30 corresponding to each page is incident on the storage crystal which is the storage medium 60.

The object light and the reference light cause interference inside the storage medium 60 for recording the hologram, and light-induced generation of mobile charge of the internal kinetic charge of the storage medium 60 according to the intensity of the interference fringes generated at this time. ) And the interference fringe is recorded through this process.

In order to read the data recorded in the storage medium 60, only the reference light needs to be irradiated to the storage medium 60. That is, when the reference light is irradiated, the interference fringe is diffracted by the reference light to restore the checkered pattern composed of the contrast of the original pixel, and then the read image is reflected on the CCD 70 to restore the original data.

That is, the data to be recorded is composed of pages and one page is composed of a plurality of pixels.

Therefore, the pixels of the SLM 50 and the CCD 70 must be matched 1: 1, and for this purpose, the optical system, that is, the CCD 70, needs to be aligned using the precision stage 80 that fixes the CCD 70.

However, in the related art, the precision stage 80 was manually moved to align the optical system including the CCD. That is, there was no adjustment device for moving the optical system finely.

However, since the optical system has to be precisely aligned in the range of 10 ⁻⁶ m to 10 ⁻⁷ m, it is difficult to move manually using human senses.

Therefore, a technique that can compensate or adjust the distortion of the optical system caused by the vibration or shock of the system that occurs from time to time is essential.

An object of the present invention is to provide an alignment adjusting device for performing precise optical alignment and adjustment using an interferometer for pixel matching of SLM and CCD in a digital hologram data storage system.

In order to achieve the above object, the present invention provides a first optical separator that separates the irradiated reference light, a storage material that emits reproduction light by restoring an interference fringe recorded by the reference light introduced from the first optical separator, and the first light. A mirror for changing the direction of the reference light introduced from the separator, a beam enlarger for enlarging the reference light reflected from the mirror, the reference light passing through the beam enlarger, and the regenerated light emitted from the storage material are incident and interfered with each other, so that the first and second A second optical separator for separating and outputting the interference fringe, a first CCD for converting the first interference fringe separated from the second optical separator into an electrical signal and outputting the output data as output data, and positioned below the first CCD Precision stage for fixing and aligning the first CCD and a second interference fringe separated from the second optical splitter into an electrical signal A second CCD for outputting a control signal, a control means for outputting a control signal for adjusting the precision stage to move the first CCD by detecting a movement of an interference fringe according to a signal output from the second CCD; And a precision stage driving means for adjusting the precision stage to move the first CCD under control of a control means.

1 is a block diagram of a general digital holographic data storage system

2 is a configuration diagram of an optical system alignment adjusting device of a digital holographic data storage system according to the present invention;

3 is a view for explaining the operation of the interferometer according to the present invention

4 is a view for explaining the movement of the interference fringe of FIG.

Explanation of symbols on the main parts of the drawings

100: light source 110, 160, 220: optical separator

120, 210: Beam magnifier 130, 200: Mirror

140: SLM 150, 180: lens group

170: storage material 190: shutter

230, 240: CCD 250: control unit

260: precision stage drive unit 270: precision stage

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

The optical system alignment adjusting device of the digital holographic data storage system according to the present invention includes an optical separator 160, a shutter 190, a mirror 200, and a beam magnifier in a general digital holographic data storage system as shown in FIG. 210, an optical splitter 220 that is an interferometer, a CCD 240, a controller 250, a precision stage 270, and a precision stage driver 260.

That is, the digital holographic data storage system according to the present invention includes a light source 100 for generating coherent light, an optical separator 110 for separating coherent light generated from the light source 100 into reference light and object light, and the light. A beam expander 10 for enlarging the object light incident from the separator 110, a mirror 130 for changing the direction of the object light enlarged by the beam expander 120, and an object light reflected from the mirror 130. An SLM 140 for inputting and modulating input data, that is, binary data of a plurality of pixels in units of pages, a lens group 150 for making a modulated object light output from the SLM 140 to a desired characteristic, and An optical separator 160 for separating the reference light irradiated from the optical separator 110 to output the storage material 170 and the mirror 200, and the lens group 150 according to the reference light introduced from the optical separator 160. Store the object light emitted from A storage material 170 for restoring the interference fringe recorded by the reference light to emit reproduction light, a lens group 180 for matching and restoring the reproduction light reproduced from the storage material 170 to a desired pixel, an optical system, That is, the shutter 190 for injecting the reference light introduced from the optical separator 160 into the mirror 200 only when the CCD 230 is aligned, and the reference introduced through the shutter 190 from the optical separator 160. Mirror 200 for changing the direction of the light, a beam expander 210 for enlarging the reference light reflected from the mirror 200, the reference light passed through the beam expander 210 and the reproduction light emitted from the storage material 170 The optical separator 220 which is incident and interfered to separate and output the first and second interference fringes, and converts the first interference fringes separated from the optical separator 220 into electrical signals and outputs the output data as output data. CCD 230, located below the CCD 230 For example, the precision stage 270 for fixing and aligning the CCD 230, the CCD 240 for converting and outputting the second interference fringe separated from the optical separator 220 into an electrical signal, and the CCD ( Control means 250 for outputting a control signal for adjusting the precision stage 270 to move the CCD 230 by detecting the movement of the interference fringe according to the signal output from the 240, and the control unit 250 It is composed of a precision stage driver 260 for adjusting the precision stage 260 to move the CCD 230 under the control of.

Here, the second interference fringe is moved by an integer multiple of the wavelength.

The operation of the optical system alignment adjustment device of the digital holographic data storage system according to the present invention configured as described above will be described.

In order to align the optical system, that is, the CCD 230, the shutter 190 is opened to allow the reference light incident from the beam separator 160 to be incident on the mirror 200 through the shutter 190.

The intermittent light irradiated from the light source 100 is separated into the reference light and the object light in the light separator 110 and is incident to the light separator 160. The optical separator 160 separates the incident reference light and emits the light toward the storage material 170 and the shutter 190.

In this case, the storage material 170 restores and outputs the interference pattern, that is, the interference fringe, recorded by the reference light incident from the optical splitter 160.

The interference fringe reconstructed from the storage material 170 is deformed into a desired shape through the lens group 180 and is incident on the optical separator 220, which is an interferometer.

On the other hand, the reference light output from the optical separator 160 is reflected by the mirror 200 by 90 ° through the open shutter 190 and then enlarged in the beam expander 210. The magnified reference light is incident on the optical splitter 220 together with the regenerated light incident from the storage material 170 to be interfered and then output as first and second interference fringes.

That is, the reproduced light causes interference by reference light incident from the beam expander 210 as shown in FIG. 3. Accordingly, the first and second interference fringes appear on the CCDs 230 and 240.

At this time, when the optical system is slightly distorted and the path of the reproduction light is changed from a 'to b', as shown in FIG. Will move.

However, the path from a 'to b' in the CCD 230 is the same as the path from a to b in the CCD 240. Therefore, if the position of the CCD 230 is moved by the precision stage 270 as much as the path from CCD 240 to a to b in the optical system, the correct position of the CCD 230 for pixel matching is achieved. Will be found.

That is, when the control unit 250 detects a path in which the interference fringe moves in the CCD 240, that is, a path from a to b, and outputs a control signal corresponding to the precision stage driver 260, the precision stage driver 260. In this case, the precision stage 260 is adjusted accordingly to move the CCD 230 by a corresponding distance.

Due to the movement of the CCD 230, pixel matching is performed as it is.

As such, when the adjustment of the optical system is completed, the shutter 190 may be closed and the shutter 190 may be opened again only when the adjustment of the optical system is required.

The process of recording and reproducing to the storage material 170 is then the same as for other digital holographic data storage systems.

That is, the interfering light irradiated from the light source 100 is separated into the reference light and the object light in the light separator 110. The object light is enlarged by the beam expander 120 and then reflected by the mirror 130 to be redirected to 90 °.

The object light reflected by the mirror 130 is modulated by the SLM 140. That is, the object light is loaded with binary data of light and shade consisting of pixels in the SLM 140, has a desired characteristic in the lens group 150, and then enters the storage material 170.

On the other hand, the reference light is output from the optical separator 110 and separated through the optical separator 160 so that some of the reference light is incident on the storage material 170.

At this time, the object light carrying data in the SLM 140 causes interference in the storage material 170 and the reference light incident from the optical splitter 160, and the storage material 170 records the interference pattern caused by the interference as an interference fringe. Done.

In addition, during reproduction, the coherent light irradiated from the light source 100 is separated into the reference light and the object light in the light separator 110 and is incident to the light separator 160.

The optical separator 160 outputs the incident reference light to the storage material 170, and the storage material 170 restores the interference pattern, that is, the interference fringe, recorded by the reference light incident from the optical separator 160. Will print.

The interference fringe reconstructed by the storage material 170 is deformed into a desired shape through the lens group 180 and then incident on the CCD 230 through the optical separator 220 to be converted into an electrical signal and output as output data.

As described above, the optical system alignment adjusting device of the digital holographic data storage system according to the present invention has the following effects.

First, the interferometer can be used to calculate the precise adjustment position of the CCD.

Second, the error due to the distortion of the optical system can be easily adjusted by moving only the CCD.

Claims (2)

A first optical separator 160 for separating the irradiated reference light; A storage material 170 for restoring the interference fringe recorded by the reference light introduced from the first optical splitter 160 to emit reproduction light; A mirror 200 for changing a direction of the reference light introduced from the first optical separator 160; A beam magnifier 210 for enlarging the reference light reflected from the mirror 200; A second optical splitter (220) for allowing the reference light passing through the beam expander (210) and the regenerated light emitted from the storage material (170) to be incident and interfered to separate and output the first and second interference fringes; A first CCD 230 which converts the first interference fringe separated from the second optical separator 220 into an electrical signal and outputs the electrical signal as output data; A precision stage 270 positioned below the first CCD 230 to fix and align the first CCD 230; A second CCD 240 for converting the second interference fringe separated from the second optical separator 220 into an electrical signal and outputting the electrical signal; Control means 250 for outputting a control signal for adjusting the precision stage 270 to move the first CCD 230 by detecting the movement of the interference fringe in accordance with the signal output from the second CCD 240 ); And Digital holographic data comprising a precision stage driving means 260 for adjusting the precision stage 260 to move the first CCD 230 according to the control of the control means 250. Optical alignment adjustment device of storage system. The method of claim 1, further comprising a shutter 190 for injecting the reference light introduced from the first optical splitter 160 into the mirror 200 only when the first CCD 230 is aligned. Optical device alignment adjusting device of digital holographic data storage system.