KR20030079035A - Holographic digital data storage system - Google Patents

Abstract

PURPOSE: A system for storing holographic digital is provided to prevent the drop in SNR of playback data generated by cross-talk, thereby minimizing image deterioration in hologram. CONSTITUTION: A beam splitter(102) splits a beam of a light source(100) into two beams. A spatial light modulator(106) modulates a first beam of the beam splitter for providing the same as an object beam. A plurality of reflecting mirrors(108,110) reflect a second beam of the beam splitter for providing the same as a reference beam. A storage medium(114) stores hologram data with the object beam and the reference beam, or reads the stored hologram data with the reference beam. A shutter(104) supplies or interrupts the first beam to the spatial light modulator. A light size controller(112) adjusts the size of the reference beam to be a set size in the case of a recording operation, and adjusts the size of the reference beam to be a size smaller than the set size in the case of a reproducing operation.

Description

Holographic Digital Storage System {HOLOGRAPHIC DIGITAL DATA STORAGE SYSTEM}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a holographic digital storage system. In particular, it is possible to eliminate cross-talk noise during wobble that causes fatal error in a holographic digital data storage system by varying the size of reference light during recording and playback. It is about technology that can be.

Currently, holographic digital data storage (Holographic Digital Data Storage) using semiconductor lasers, charge coupled devices (CCDs), liquid crystal displays (LCDs), and the like are being actively researched and developed. Holographic digital data storage devices have the advantages of large capacity and ultra-fast data transfer rate, so they are not only being used as fingerprint recognition devices and display devices for storing and reproducing fingerprints, but also their application fields are gradually expanding. .

Such a holographic digital data storage device interferes with the object light transmitted from the target object and the reference light, and then reacts the interference fringe generated by the interference differently according to the amplitude and phase of the interference fringe. Three-dimensional hologram data is stored by recording in a storage medium such as refractive crystal or polymer. The object light is blocked and only the reference light is provided to the storage medium to reproduce the stored three-dimensional hologram data.

1 is a block diagram showing a holographic digital storage system for spatial multiplexing according to the prior art. Referring to FIG. 1, a conventional holographic digital storage and system for spatial multiplexing includes a light source 10, a light separator 12, a shutter 14, a reflector 18, 20, a spatial light modulator (SLM) ( 16), storage medium 22, CCD 24. The optical splitter 12 separates the laser beam of the light source 10 into two, so that the two paths including the plurality of optical systems, that is, the reference light path S ₁ and the object, are separated between the optical splitter 12 and the storage medium 22. An optical path S ₂ is formed.

First, the optical splitter 12 separates the laser light incident from the light source 10 into reference light and light of an object, wherein the separated reference light of vertical or horizontal polarization is provided to the reference light path S ₂ and separated. The object light has the same polarization direction as the reference light and is provided in the object light path S ₁ .

The reference light separated from the optical separator 12 and vertically polarized to the reflector 18 is adjusted through an optical lens (not shown) and expanded to an arbitrary size (extended to a sufficient size to cover the size of the object light). The light is incident on the storage medium 22 after being deflected by a predetermined angle, for example, a recording or reproducing angle, through the other reflecting mirror 20.

On the other hand, the object light separated from the light separator 12 and incident through the opening of the shutter 14 is transmitted to the spatial light modulator 16. The shutter 14 is kept open when data is recorded, and is kept blocked when data is reproduced. The spatial light modulator 16 modulates the object light in units of one page of binary data of light and dark, which form pixels, according to external input data. The object light modulated in this manner is incident on the storage medium 22 in synchronization with the reference light.

In the storage medium 22, an interference fringe obtained through interference between the modulated object light provided from the spatial light modulator 16 and the corresponding reference light at the time of recording is recorded. That is, the light induced phenomenon of the kinetic charge is generated inside the storage medium 22 according to the intensity of the interference fringe caused by the interference between the modulated object light and the reference light, and through this process, the storage medium 22 has a three-dimensional image. Interference fringes of the hologram data are recorded. The spatial multiplexing holographic digital storage system then moves the storage medium 22 to record data.

On the contrary, when the object light separated from the optical separator 12 is blocked by the shutter 14 during reproduction, and the reference light for reproduction is incident on the storage medium 22 through the reflecting mirrors 18 and 20, the recording medium 22 records the data. The reproduced reference light in which the interference fringe is incident is diffracted to reproduce the recorded signal and send it to the CCD 24. The CCD 24 restores the reproduction signal sent from the storage medium 22 to an electrical signal and outputs three-dimensional hologram data.

2A and 2B are diagrams illustrating a case in which there is no shaking of a storage medium and a case of shaking in the holographic digital storage system for spatial multiplexing of FIG. 1.

Referring to FIG. 2A, the holographic digital storage system for spatial multiplexing accurately enters the reference light for reproduction into a recording area (eg, a1 and a2) only when shaking does not occur while moving the storage medium 22 during reproduction. To play the data. However, as shown in FIG. 2B, when shaking occurs in the storage medium 22, the diffraction efficiency of the reference light is weakened. In particular, the reproduction reference light passes through the adjacent recording areas a1 and a2 as w, thereby generating cross-talk. Noise caused by such cross-talk makes it difficult to accurately reproduce data of a desired area in a holographic digital storage system for spatial multiplexing.

FIG. 3 is a block diagram showing a holographic digital storage system for shift multiplexing according to the prior art, in which the lens 26 is disposed in the reference light path S ₁ to the storage medium 22 in the spatial multiplexing structure shown in FIG. Is further provided. That is, in the holographic digital storage system for shift multiplexing, the reference light is extended to the storage medium 22 through the lens 26, and the rest of the operation is the same as the system for spatial multiplexing.

FIG. 4 is a diagram for describing a case in which a storage medium is shaken during reproduction in the holographic digital storage system for shift multiplexing of FIG. 3.

Referring to FIG. 4, in the holographic digital storage system for shift multiplexing, when a reproduction does not occur while moving the storage medium 22, the reference light for accurate reproduction is incident on the recording area (for example, a1 and a2). To play the data. That is, in the case of shift multiplexing, if the half angle of the recording and reproduction angle of the reference light is a as shown in the figure, the original reproduction angle is -a to + a. However, if a shake occurs in the storage medium and the shake angle is β, the reference light at the time of reproduction is reproduced as -a-β to + a-β (or -a + β to + a + β). In particular, the greater the degree of shaking, the more the result is the simultaneous reproduction of data recorded in an adjacent area of the storage medium 22, which causes cross-talk. This cross-talk eventually causes the signal-to-noise ratio (SNR) of the reproduction data to be lowered, causing a deterioration of image quality in the reproduced hologram.

Therefore, in the conventional holographic digital storage system for space / shift multiplexing, data is recorded at intervals larger than the selection ratio of the recording area in order to minimize cross-talk even when the storage medium is shaken during playback, which reduces the storage capacity. do.

An object of the present invention is to solve the above problems of the prior art by varying the size of the reference light at the time of recording and reproducing, so that the cross caused by the shaking that causes the fatal error in the holographic digital data storage system for space / shift multiplexing To provide a holographic digital storage system that prevents torque.

In order to achieve the above object, the present invention provides a recording and reproducing apparatus of a holographic digital data storage system, comprising: an optical splitter for splitting light of a light source into two, and a space for modulating the first light of the optical splitter to provide object light An optical modulator, a reflector for reflecting the second light of the optical splitter to provide the reference light, a storage medium for storing the hologram data or reading the hologram data stored as the reference light with the object light of the spatial light modulator and the reference light reflected from the reflector; A shutter for supplying or blocking the first light of the optical splitter to the spatial light modulator, and adjusting the reference light of the reflector to a set size during recording operation in which the object light is irradiated to the storage medium through the shutter, Adjust the reflector's reference light to less than the set size during reproducing operation when no light is irradiated to the storage medium It is provided with an optical size regulator.

In order to achieve the above object, another apparatus of the present invention is a recording and reproducing apparatus of a holographic digital data storage system, comprising: an optical splitter for splitting light of a light source into two, and a first light of the optical splitter to modulate the light into an object light; The hologram data is stored or the hologram data is stored as the reference light reflected from the object light and the reflector of the spatial light modulator, and the reflector provides the reference light by reflecting the second light of the optical splitter. A medium, a shutter for supplying or blocking the first light of the optical splitter to the spatial light modulator, a lens for extending the reference light of the reflector to provide the storage medium, and object light from the spatial light modulator through the shutter to the storage medium During the recording operation, adjust the reference light of the reflector to the set size and ensure that no object light To Saint-operating with a light to reduce size adjuster adjusts the reference light angle, it extends through the lens than the set size.

1 is a block diagram showing a holographic digital storage system for spatial multiplexing according to the prior art,

2A and 2B are diagrams illustrating a case where there is no shaking of a storage medium and a case of shaking when playing in the holographic digital storage system for spatial multiplexing of FIG. 1;

3 is a block diagram showing a holographic digital storage system for shift multiplexing according to the prior art;

FIG. 4 is a diagram for describing a case in which a storage medium is shaken during reproduction in the holographic digital storage system for shift multiplexing of FIG. 3; FIG.

5 is a block diagram showing a holographic digital storage system for spatial multiplexing according to the present invention;

FIG. 6 is a diagram illustrating safely playing even when a storage medium is shaken in the holographic digital storage system for spatial multiplexing of FIG. 5; FIG.

7 is a block diagram illustrating a holographic digital storage system for shift multiplexing according to the present invention;

8 is a diagram illustrating safely playing even if a shake of a storage medium occurs in the holographic digital storage system for shift multiplexing of FIG.

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

100: light source 102: optical separator

104: shutter 106: spatial light modulator

108, 110: reflector 112: optical size adjuster

114: storage medium 116: CCD

118 lens

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

5 is a block diagram illustrating a holographic digital storage system for spatial multiplexing according to the present invention.

Referring to FIG. 5, the holographic digital storage and system for spatial multiplexing of the present invention comprises a light source 100, a light separator 102, a shutter 104, reflectors 108, 110, a spatial light modulator 106, and storage. Medium 114, CCD 116, and light scale controller 112. The optical splitter 102 separates the laser beam of the light source 100 into two, so that the two paths including the plurality of optical systems, that is, the reference light path S ₁ and the object, are separated between the optical splitter 102 and the storage medium 114. An optical path S ₂ is formed.

First, the optical splitter 102 separates the laser light incident from the light source 100 into reference light and light of an object, wherein the separated reference light of vertical or horizontal polarization is provided to the reference light path S ₂ and separated. The object light has the same polarization direction as the reference light and is provided in the object light path S ₁ .

Object light that is separated from the light separator 102 and is incident through the opening of the shutter 104 is transmitted to the spatial light modulator 106. The shutter 104 maintains an open state during data recording and a cutoff state during data reproduction. The spatial light modulator 106 modulates the object light in units of one page of binary data of light and dark, which form pixels, according to external input data. The object light modulated as described above is incident to the storage medium 114 in synchronization with the reference light during data recording.

On the other hand, the reference light separated from the light separator 102 and vertically polarized to the reflector 108 is adjusted through an optical lens (not shown) and expanded to an arbitrary size (extended to a sufficient size to cover the size of the object light). And is deflected through a different reflector 110 at a predetermined angle, for example, a recording or reproducing angle. In recording, the optical size controller 112 adjusts the reference light of the reflector to the set size X1 and then enters the storage medium 114.

The storage medium 114 then records the interference fringes of the three-dimensional hologram data obtained through the interference between the modulated object light provided from the spatial light modulator 106 and the corresponding reference light at the time of recording.

On the contrary, the object light separated from the optical separator 102 is blocked by the shutter 104 during data reproduction. When the reproduction reference light separated by the optical separator 102 is reflected through the reflectors 108 and 110 and enters the optical size controller 112, the optical size controller 112 adjusts the size of the reference light set at the time of reproduction (X2). do. This will be referred to Equation 1.

Here, X1 is the size of the reference light at the time of recording, L is the thickness of the storage medium, and β is the maximum permissible angle of the storage medium.

As shown in Equation 1, it can be seen that the magnitude X2 of the reference light at the time of reproduction is smaller than the magnitude of the reference light at the time of recording.

As a result, when the reference light X2 enters the storage medium 114 during reproduction, the storage medium 114 diffracts the reproduction reference light into which the recorded interference fringe is incident, reproduces the recorded signal, and sends the recorded signal to the CCD 116. The CCD 116 restores the reproduction signal sent from the storage medium 114 to an electrical signal and outputs three-dimensional hologram data.

FIG. 6 is a diagram for safely playing even if a shake of a storage medium occurs in the holographic digital storage system for spatial multiplexing of FIG. 5. As shown in FIG. 6, when the shake occurs in the storage medium 116 during reproduction, since the reference light X2 is smaller in size than the reference light X1 at the time of recording, the recording area a1, prevents cross-talk occurring in a2). Therefore, according to the present invention, the holographic digital storage system for spatial multiplexing can accurately reproduce only data of a desired area.

7 is a block diagram illustrating a holographic digital storage system for shift multiplexing according to the present invention. 7, holographic digital storage and system for shift multiplexing of the present invention comprises a light source 100, a light separator 102, a shutter 104, a reflector 108, 110, a spatial light modulator 106, a storage Medium 114, CCD 116, lens 118, and light scale controller 112.

Object light that is separated from the light separator 102 and incident through the opening of the shutter 104 is transmitted to the spatial light modulator 106. The shutter 104 maintains an open state during data recording and a cutoff state during data reproduction. The spatial light modulator 106 modulates the object light in units of one page of binary data of light and dark, which form pixels, according to external input data. The object light modulated in this manner is incident on the storage medium 114 in synchronization with the reference light for data recording.

On the other hand, the reference light separated from the light separator 102 and vertically polarized to the reflector 108 is adjusted through an optical lens (not shown) and expanded to an arbitrary size (extended to a sufficient size to cover the size of the object light). And is deflected through a different reflector 110 at a predetermined angle, for example, a recording or reproducing angle. When data is recorded, the optical size controller 112 adjusts the reference light of the reflector to the set size X1 and enters the storage medium 114.

The storage medium 114 then records the interference fringes of the three-dimensional hologram data obtained through the interference between the modulated object light provided from the spatial light modulator 106 and the corresponding reference light at the time of recording.

On the contrary, the object light separated from the optical separator 102 is blocked by the shutter 104 during data reproduction. When the reproduction reference light separated by the optical separator 102 is reflected through the reflectors 108 and 110 and enters the optical size controller 112, the optical size controller 112 adjusts the size of the reference light set at the time of reproduction (X2). do. This will be referred to Equation 2.

Here, X1 is the magnitude of the reference light in recording, f is the focal length of the lens 118, a is the angle of incidence of the reference light of the lens 118, and β is the maximum permissible angle of the storage medium.

As shown in Equation 2, it becomes smaller than the size X2 of the reference light at the time of reproduction, which narrows the angular range of the reference light incident on the storage medium to prevent noise due to cross-talk from data of adjacent pages.

As a result, when the reference light X2 enters the storage medium 114 during reproduction, the storage medium 114 diffracts the reproduction reference light into which the recorded interference fringe is incident, reproduces the recorded signal, and sends the recorded signal to the CCD 116. The CCD 116 restores the reproduction signal sent from the storage medium 114 to an electrical signal and outputs three-dimensional hologram data.

FIG. 8 is a diagram illustrating safely playing even if a shake of a storage medium occurs in the holographic digital storage system for shift multiplexing of FIG. 7.

Referring to FIG. 8, the holographic digital storage system for shift multiplexing reproduces data by injecting the reference light X2 for reproduction accurately into the recording area only when shaking does not occur during the movement of the storage medium 114 during reproduction. do. In the present invention, when the half angle of the recording reference light is a, the original reproduction angle is -a to + a. However, if the shake angle β occurs due to the shaking in the storage medium, the reference light X2 at the time of reproduction is within the range of -a-β to + a-β (or -a + β to + a + β). You can safely play back the data in the area without playing back the data. Therefore, the holographic digital storage system for shift multiplexing of the present invention prevents cross-talk due to shaking of the storage medium during data reproduction.

As described above, in the holographic digital data storage system for space / shift multiplexing, the size of the reference light is different at the time of data recording and reproduction. The generated cross-talk can be prevented beforehand.

Therefore, the present invention can prevent the degradation of the signal-to-noise ratio (SNR) of the reproduction data due to cross-talk, thereby minimizing image quality deterioration in the reproduced hologram. In addition, the present invention has the advantage that it is not necessary to record data at a larger interval than the selection of the recording area in order to reduce cross-talk due to shaking.

On the other hand, the present invention is not limited to the above-described embodiment, various modifications are possible by those skilled in the art within the spirit and scope of the present invention described in the claims to be described later.

Claims (4)

In the recording and reproducing apparatus of the holographic digital data storage system, A light separator that splits the light of the light source into two; A spatial light modulator for modulating the first light of the optical splitter to provide object light; A reflector reflecting the second light of the optical separator to provide the reference light; A storage medium storing hologram data as a reference light reflected by the object light and the reflector of the spatial light modulator or reading hologram data stored as the reference light; A shutter for supplying or blocking the first light of the optical splitter to the spatial light modulator; And Adjust the reference light of the reflector to a predetermined size in a recording operation in which the object light is irradiated to the storage medium through the shutter, and set the reference light of the reflecting mirror in the reproducing operation in which the object medium is not irradiated to the storage medium. Holographic digital storage system characterized in that it comprises a light size adjuster for adjusting the reference light of the smaller than the set size. The holographic digital storage system according to claim 1, wherein the magnitude (X2) of the reference light at the time of reproduction is adjusted by the following equation. Where X1 is the size of the reference light during the recording operation, L is the thickness of the storage medium, and β is the maximum permissible angle of the storage medium. In the recording and reproducing apparatus of the holographic digital data storage system, A light separator that splits the light of the light source into two; A spatial light modulator for modulating the first light of the optical splitter to provide object light; A reflector reflecting the second light of the optical separator to provide the reference light; A storage medium storing hologram data as a reference light reflected by the object light and the reflector of the spatial light modulator or reading hologram data stored as the reference light; A shutter for supplying or blocking the first light of the optical splitter to the spatial light modulator; A lens that extends the reference light of the reflecting mirror and provides it to the storage medium; The reference light of the reflector is adjusted to a predetermined size in a recording operation in which the object light is irradiated to the storage medium through the shutter, and is extended through a lens in a reproducing operation in which the object light is not irradiated to the storage medium. Holographic digital storage system characterized in that it comprises a light size adjuster for adjusting the angle of the reference light smaller than the set size. 4. The holographic digital storage system according to claim 3, wherein the magnitude (X2) of the reference light at the time of reproduction is adjusted by the following equation. Where X1 is the size of the reference light during recording operation, f is the focal length of the lens, a is the angle of incidence of the reference light of the lens, and β is the maximum permissible angle of the storage medium.