KR20070002989A - Writing and reading device on the holographic digital data storage system - Google Patents

Abstract

A recording/reproducing device of an HDDS(Holographic Digital Data Storage) system is provided to adjust an incident angle of a reference beam incident on a storage medium through an actuator to which a pickup lens is attached, thereby reducing size of the overall system. Light sources(100,102) generate beams. An SLM(Spatial Light Modulator)(108) transmits some of the beams through a reference beam area, and transmits the rest of the beams through holographic data patterns to modulate the beams into signal beams. An actuator(106) is attached with a pickup lens(106a) for transmitting the beams delivered from the SLM, and moves a position of the pickup lens. A lens(110) transmits the beams delivered through the pickup lens in parallel at preset angles, so that the beams are incident on a storage medium(112) as reference beams, and transmits the signal beams to make the signal beams incident on the storage medium.

Description

Recording and playback device for holographic digital data storage system {WRITING AND READING DEVICE ON THE HOLOGRAPHIC DIGITAL DATA STORAGE SYSTEM}

1 is a block diagram showing a recording and reproducing apparatus of a holographic digital data storage system according to the prior art;

2 is a block diagram schematically illustrating a recording and reproducing apparatus of a holographic digital data storage system according to an embodiment of the present invention;

3 is a block diagram schematically illustrating a recording and reproducing apparatus of a holographic digital data storage system according to another embodiment of the present invention;

4 is a block diagram schematically illustrating a recording and reproducing apparatus of a holographic digital data storage system according to another embodiment of the present invention;

5 shows a spatial light modulator used in the recording and reproducing apparatus of another embodiment and another embodiment of the present invention.

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

100, 102 light source 106 actuator

106a: pickup lens 108: spatial light modulator (SLM)

110, 114: Fourier lens 112: storage medium

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a holographic digital data storage system (HDDS), and more particularly, to a recording and reproducing apparatus of a holographic digital data storage system capable of greatly reducing the system size.

Currently, technologies for storing holographic digital data are being actively researched in various fields, for example, thanks to remarkable developments such as semiconductor lasers, charge coupled devices (CCDs), and liquid crystal displays (LCDs). As a result, fingerprint recognition systems for storing and reproducing fingerprints have been put to practical use, and are being expanded to various fields that can apply the advantages of large storage capacity and ultra-fast data transfer speed. Among them, a holographic digital data storage system for storing a large amount of data is a storage medium, for example, optically, in which an interference fringe generated when the signal light from a target object and a reference light interfere with each other is sensitive to the amplitude of the interference fringe. By recording to a storage medium such as a photorefractive crystal, it is possible to display three-dimensional images of an object and to generate hundreds to thousands of hologram data composed of pages of binary data. Can be stored in the same place.

1 is a block diagram showing a recording and reproducing apparatus of a holographic digital data storage system according to the prior art.

Referring to FIG. 1, a recording and reproducing apparatus of a conventional holographic digital data storage system includes a light source 10, a light splitter 14, and a spatial light modulator (SLM) ( 16, a reflection mirror 20, a rotation mirror 24, a storage medium 28, a CCD 32 and the like. Here, reference numeral 12 denotes an optical magnifying lens, 18 and 30 a Fourier lens, and 26 an actuator for adjusting the angle of the rotation mirror 24 to adjust the angle of incidence of the reference light into the storage medium 28. Although not shown in the figure, a shutter is additionally installed in the optical path between the optical separator 14 and the storage medium 28.

The light source 10 generates laser light, and the light separator 14 splits the light generated by the light source 10 into a path of a reference beam Sref and a signal beam Sobj. The spatial light modulator (SLM) 16 carries holographic data, that is, binary data of a plurality of pixels in units of pages, and modulates them into signal light by the light splitted by the optical separator 14. The reflection mirror 20 reflects the light branched from the optical separator 14, and the rotation mirror 24 converts the angle reflected by the reflection mirror 20 into the storage medium 28 and provides it as a reference light. do. The storage medium 28 records the interference fringe generated by the interference of the signal light output from the spatial light modulator (SLM) 16 at the time of recording and the reference light reflected from the rotation mirror 24, and recorded by the incident of the reference light at the time of reproduction. The interference fringe is diffracted and output. When only one reference light is incident on the storage medium 28 and the one-page binary pixel data image recorded in the form of an interference fringe is reproduced, the CCD 32 converts the reproduced data image into electrical data and outputs it.

The recording and reproducing apparatus of the holographic digital data storage system configured as described above operates as follows.

First, the laser light generated by the light source 10 during recording is incident on the optical separator 14 through the light magnifying lens 12, and the optical separator 14 converts the incident light into two light beams for the reference light and the signal light path. Branch The light branched from the optical separator 14 is input to the spatial light modulator (SLM) 16 and modulated into the signal light Sobj. That is, the signal light Sobj is incident on the storage medium 28 through the Fourier lens 18 after being modulated in units of one page of the binary data of the contrast made by the actual pixels through the spatial light modulator (SLM) 16. . The other light separated by the optical separator 14 is reflected by the reflection mirror 20 and the rotation mirror 24, and is reflected at the recording angle set through the rotation mirror 24 to store the storage medium as the reference light Sref. 28). The signal light Sobj and the reference light Sref overlap each other inside the storage medium 28 for recording the hologram to cause interference, and the light induction of the internal kinetic charge of the storage medium 28 depends on the intensity of the interference fringe generated at this time. An interference pattern is recorded on the recording material layer by a light-induced generation of mobile charge.

In addition, the laser light generated by the light source 10 (for example, a laser light having a wavelength of 532 nm) during reproduction is transmitted to the optical separator 14 through the optical magnifying lens 12, and the incident light is emitted from the optical separator 14. Branches into two lights. The light branched from the optical separator 14 is input to the spatial light modulator (SLM) 18 and modulated into a signal light Sobj, and the shutter (not provided) is installed in the optical path between the optical separator 14 and the storage medium 28. Not shown to the storage medium 28). However, other light branched from the optical separator 14 is reflected by the reflecting mirror 20, and the reflected light is stored as the reference light Sref having the same angle as the preset recording angle by the rotating mirror 24. Is incident on the medium 28. That is, the reference light Sref at which the angle of the rotating mirror 24 is changed in correspondence with each stored page is incident on the disk which is the storage medium 28.

If only the reference light Sref is incident on the storage medium 28 while the signal light Sobj is blocked, a one-page binary pixel data image composed of original pixel contrasts in the storage medium 28 on which interference data is recorded ( That is, a checkerboard pattern) is reproduced. The binary pixel data image (one page unit) Sread reproduced from the storage medium 28 is transferred to the CCD 32 through the Fourier lens 30, and the CCD 32 receives the reproduced data image Sread. The data is converted into an electrical data signal, and the converted data is restored to original data through an image signal processor, a decoder, and the like, which are not shown.

However, when the recording and reproducing apparatus of the holographic digital data storage system according to the related art is an angle multiplexing method, it is incident to the storage medium 28 by adjusting the angle of the rotating mirror 24 through the actuator 26. The angle of the reference light Sref to be converted is overwritten and recorded at the same position of the storage medium 28. At this time, a pair of lenses (not shown) is included between the rotating mirror 24 and the storage medium 28 to be equal to the focal length 4F from the spatial light modulator (SLM) 16 to the CCD 32. Although the focal length 4F is adjusted, there is a problem in that the size of the system increases.

Summary of the Invention An object of the present invention is to solve the above-mentioned problems of the prior art, and the holographic digital data which can reduce the size of the entire system by adjusting the angle of incidence of the reference light incident on the storage medium through an actuator with a pickup lens. There is provided a recording and reproducing apparatus of a storage system.

In order to achieve the above object, the present invention provides a device for recording data by superimposing a reference light of a predetermined angle and a signal light having data information on a storage medium of a holographic digital data storage system, comprising: a light source for generating light and a part of the light; Is transmitted through the reference light region, a spatial light modulator for transmitting the remaining portion of the light through the holographic data pattern to be modulated into a signal light, and a pickup lens for transmitting the light transmitted from the spatial light modulator is attached and the position of the pickup lens is moved. A pair of lenses for transmitting the signal light transmitted from the spatial light modulator, and a light transmitted through the pickup lens in parallel at a predetermined angle to be incident on the storage medium as reference light and transmitted through the pair of lenses. Including a lens that transmits signal light and enters the storage medium .

In order to achieve the above object, another apparatus of the present invention is a device for recording data by superimposing a reference light of a predetermined angle and a signal light having data information on a storage medium of a holographic digital data storage system, comprising: a light source for generating light; And a pickup lens for transmitting a part of the light of the light source, and an actuator for shifting the position of the pickup lens, and transmitting the light transmitted through the pickup lens as reference light in parallel at a predetermined angle to transmit the remaining light portion of the light source. A spatial light modulator that transmits the lens and the reference light transmitted through the lens to the storage medium by transmitting it through the reference light region, and transmits the light transmitted through the lens through the holographic data pattern to modulate the signal light and enter the storage medium. Include.

In order to achieve the above object, another apparatus of the present invention is a device for reproducing data by injecting reference light at a predetermined angle into a storage medium of a holographic digital data storage system, wherein a pickup lens for transmitting light is attached to the pickup lens. An actuator for moving the position of the lens, and a lens for transmitting the light transmitted through the pickup lens in parallel at a predetermined angle to enter the storage medium as a reference light.

In order to achieve the above object, another apparatus of the present invention is a device for reproducing data by injecting reference light at a predetermined angle into a storage medium of a holographic digital data storage system, wherein a pickup lens for transmitting light is attached to the pickup lens. An actuator for moving the position of the lens, a lens for transmitting the light transmitted through the pickup lens in parallel at a predetermined angle to be transmitted to the reference light, and a space for transmitting the reference light transmitted through the lens through the reference light region to enter the storage medium. An optical modulator.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

2 is a block diagram schematically illustrating a recording and reproducing apparatus of a holographic digital data storage system according to an embodiment of the present invention.

Referring to FIG. 2, a recording and reproducing apparatus of a holographic digital data storage system according to an embodiment of the present invention includes an actuator having a first light source 100 and a second light source 102 and a pickup lens 106a attached thereto. 106, spatial light modulator (SLM) 108, Fourier lenses 110 and 114, storage medium 112, CCD 116 and the like. Unexplained reference numeral 104 denotes an optical magnifying lens. Although not shown in the figure, a shutter is added to the signal light path between the second light source 102 and the Fourier lens 110. Here, F represents the focal length and the focal length from the spatial light modulator (SLM) 108 to the CCD 116 is 4F in total.

The first and second light sources 100 and 102 generate laser light for the reference light signal Sref and the signal light signal Sobj, respectively.

The actuator 106 to which the pickup lens 106a is attached has a focal length of 2F to the Fourier lens 110. Since the light position of the first light source 100 incident on the Fourier lens 110 is changed through the 2F focal length according to the vertical position of the pickup lens 106a, the vertical movement of the pickup lens 106a according to the actuator 106 is performed. The position of the laser beam of the first light source 100 that has passed through the pickup lens 106a is incident on the Fourier lens 110, thereby changing the position of the storage medium 112 in the form of parallel light through the Fourier lens 110. The angle of the reference light incident on the target is changed.

The spatial light modulator (SLM) 108 carries a holographic data composed of pages in units of laser light generated from the second light source 102 passing through the optical magnifying lens 104 and modulates the holographic data into a signal light Sobj to perform a Fourier lens. Forward to 110.

The Fourier lens 110 installed at the front end of the storage medium 112 receives the laser light transmitted through the pickup lens 106a of the actuator 106 and the signal light Sobj modulated by the spatial light modulator (SLM) 108. It has a diameter size for permeation. The Fourier lens 110 converts the laser light passing through the pickup lens 106a of the actuator 106 transmitted through the lens outside into a reference light Sref traveling in parallel at an angle to the storage medium 112. do. The Fourier lens 110 collects the modulated signal light Sobj through the SLM 108 and transmits the modulated signal light Sobj to the storage medium 112.

The storage medium 112 detects an interference fringe generated by interference of the reference light Sref incident through the Fourier lens 110 as parallel light at an angle and the signal light Sobj modulated from the spatial light modulator SLM 108. Record it. In this case, in the recording apparatus according to the exemplary embodiment, the position where the laser light of the first light source 100 passing through the pickup lens 106a is incident on the Fourier lens 110 by the vertical movement of the actuator 106 is determined. The hologram data is overlaid and recorded at the same position of the storage medium 112 by an angle multiplexing method while the reference light angle changed to become parallel light through the Fourier lens 110 and incident on the storage medium 112 is changed.

The Fourier lens 114 located at the rear end of the storage medium 112 transmits the binary pixel data image (one page unit) Sread reproduced from the storage medium 112 to the CCD 116 and transmits the CCD (116). In 116, the reproduced data image Sread is photographed and the photographed signal is converted into an electrical data signal. The data converted by the CCD 116 is restored to original data through an image signal processor, a decoder, and the like, which are not shown in the drawing.

The recording and reproducing apparatus of the holographic digital data storage system according to an embodiment of the present invention configured as described above operates as follows.

First, a laser light generated from the first light source 100 (for example, a laser light having a wavelength of 532 nm) during recording passes through a pickup lens 106a of the actuator 106 moved to a position corresponding to a preset reference light angle, thereby performing a Fourier lens ( 110). The laser light generated by the second light source 102 (for example, laser light having a wavelength of 532 nm) is signal light of holographic data configured in units of pages through the spatial light modulator (SLM) 108 via the optical magnifying lens 104. It is modulated to Sobj and transmitted to the Fourier lens 110.

The laser light transmitted through the pickup lens 106a of the actuator 106 is converted to the reference light Sref, which is parallel light having a preset recording angle, through the Fourier lens 110 and transmitted to the storage medium 112. The signal light Sobj modulated by the spatial light modulator SLM 108 is collected through the Fourier lens 110 and transmitted to the storage medium 112.

The reference light Sref and the signal light Sobj modulated from the spatial light modulator SLM 108, which are incident on parallel light at a predetermined angle through the Fourier lens 110, overlap each other in the recording material layer of the storage medium 112. To cause interference, and the interfered pattern is recorded according to the intensity of the generated interference pattern. Accordingly, in the apparatus of the present embodiment, the angle of the reference light Sref incident on the storage medium 112 through the Fourier lens 110 can be adjusted by adjusting the position of the actuator 106 pickup lens 106a by vertical movement. It is possible to superimpose hologram data on the storage medium 112 in a multiplexing manner.

On the other hand, the laser light generated by the first light source 100 during reproduction is transmitted to the Fourier lens 110 through the pickup lens 106a of the actuator 106 moved to a position according to a predetermined reference light angle. However, the laser light generated by the second light source 102 is not transmitted to the storage medium 112 by a shutter (not shown) added between the second light source 102 and the Fourier lens 110.

The laser light transmitted through the pickup lens 106a of the actuator 106 is converted to the reference light Sref, which is parallel light having a preset recording angle, through the Fourier lens 110 and transmitted to the storage medium 112.

That is, when only the reference light Sref is incident on the storage medium 112 while the signal light Sobj is blocked, the holographic data image Sread composed of binary pixel contrasts recorded on the storage medium 112 is reproduced. .

The holographic data image Sread reproduced from the storage medium 112 passes through the Fourier lens 114 to the CCD 116, and the CCD 116 converts the reproduced data image Sread into an electrical data signal. The converted data is restored to the original data through an image signal processor, a decoder, and the like, which are not shown.

3 is a schematic diagram of a recording and reproducing apparatus of a holographic digital data storage system according to another embodiment of the present invention.

 Referring to FIG. 3, a recording and reproducing apparatus of a holographic digital data storage system according to another embodiment of the present invention includes a light source 200, a spatial light modulator (SLM) 204 having a reference light transmitting region, and a pickup lens. Actuator 206 with attached 206a, lenses 208, Fourier lenses 210 and 214, storage medium 212, CCD 216 and the like. Unexplained reference numeral 202 denotes an optical magnification lens, and the lenses 202 denote a pair of projection lenses in a 1: 1 manner. Although not shown in the figure, a shutter is added to the signal light path between the spatial light modulator (SLM) 204 and the Fourier lens 210. Here, F represents a focal length and the focal length from the image formed in the pair of lenses 202 to the CCD 216 is 4F in total.

The light source 200 generates laser light for the reference light Sref path and the signal light Sobj path and transmits the laser light to the light magnifying lens 202.

The spatial light modulator (SLM) 204 transmits a portion of the light that has passed through the optical magnifying lens 202 through the holographic data pattern (b of FIG. 5) configured in units of pages to modulate the signal light Sobj to generate a pair. To the lenses 208. In addition, the spatial light modulator (SLM) 204 of the present embodiment transmits another part of the light passing through the optical magnifying lens 202 through the reference light transmitting region (a of FIG. 5), and the actuator to which the pickup lens 206a is attached ( 206). Here, the reference light transmitting region (a in FIG. 5) of the spatial light modulator (SLM) 204 may have various shapes such as a circle and a rectangle.

The actuator 206 to which the pickup lens 206a is attached has a focal length of 2F to the Fourier lens 210 and is incident on the Fourier lens 210 through the 2F focal length according to the vertical position adjustment of the pickup lens 206a. The light position is different. Since the position of the light passing through the pickup lens 206a is incident on the Fourier lens 210 by the vertical movement of the pickup lens 206a of the actuator 206, the parallel light is formed through the Fourier lens 210. The angle of the reference light Sref incident on the storage medium 212 is changed.

The pair of lenses 208 of the 1: 1 method enlarge the Fourier lens by enlarging the signal light Sobj modulated by the spatial light modulator (SLM) 204 at the focal position F in front of the Fourier lens 210. Forward to 210. That is, the distance between the last lens and the Fourier lens 210 in the pair of lenses 208 is 2F.

The Fourier lens 210 receives the reference light Sref transmitted through the pickup lens 206a of the actuator 206 and the signal light Sobj modulated by the light modulator SLM 208 through the pair of lenses 208. All have a diameter size for transmission. The Fourier lens 210 converts the light passing through the pickup lens 206a of the actuator 206 transmitted through the lens outside into a reference light Sref traveling in parallel at a predetermined recording angle to the storage medium 212. To pass. The Fourier lens 210 collects the modulated signal light Sobj of the SLM 208 passing through the pair of lenses 208 and transmits the modulated signal light Sobj to the storage medium 212.

The storage medium 212 is an interference fringe generated by interference of the reference light Sref incident through the Fourier lens 210 as parallel light at a predetermined angle and the signal light Sobj modulated by the spatial light modulator SLM 204. Record it.

The Fourier lens 214 located at the rear end of the storage medium 212 transmits the binary pixel data image (one page unit) Sread reproduced from the storage medium 212 to the CCD 216 and transmits the CCD (216). In 216, the reproduced data image Sread is photographed, and the photographed signal is converted into an electrical data signal, and then restored to original data through an image signal processor, a decoder, and the like, which are not shown in the drawing.

The recording and reproducing apparatus of the holographic digital data storage system according to another embodiment of the present invention configured as described above operates as follows.

First, laser light (for example, laser light of 532 nm wavelength) generated in the light source 200 during recording is magnified through the light magnifying lens 202 and transmitted to the spatial light modulator (SLM) 204.

The spatial light modulator (SLM) 204 transmits a part of the light enlarged through the optical magnifying lens 202 in a holographic data pattern (b of FIG. 5) configured in units of pages, and modulates the signal into a signal light Sobj. An actuator 206 to which the pick-up lens 206a is attached by transmitting to the pair of lenses 208 and simultaneously transmitting another portion of the light that has passed through the light magnifying lens 202 through the reference light transmitting region (a of FIG. 5). To pass on.

Light transmitted through the spatial light modulator (SLM) 204 by the pickup lens 206a of the actuator 206 moved to the vertical position according to the preset recording angle is transmitted to the Fourier lens 110 to be preset. The light is transferred to the storage medium 212 by converting the light into a reference light Sref which is parallel light.

The signal light Sobj modulated by the spatial light modulator (SLM) 204 is transmitted to the Fourier lens 210 through a pair of lenses 208 in a 1: 1 manner.

The reference light (Sref) and the signal light (Sobj) modulated by the spatial light modulator (SLM) 204, which are incident to parallel light at a predetermined angle, which are two lights passing through the Fourier lens 210, are recorded in the recording medium 212. Interference overlaps with each other in the layer, causing interference, and the interference pattern is recorded according to the intensity of the interference pattern generated at this time. In this case, when the actuator 206 pick-up lens 206a is moved vertically, the angle of incidence of the reference light Sref incident on the storage medium 212 through the Fourier lens 210 may be adjusted, thereby allowing the storage medium to be angle-multiplexed. At 212, superimposition recording of hologram data is possible.

On the other hand, during reproduction, the light source 200 to the Fourier lens may be blocked while blocking the signal light Sobj to the storage medium 212 by a shutter added to the signal light path between the spatial light modulator (SLM) 204 and the Fourier lens 210. When only the reference light Sref enters the storage medium 212 through 210, the holographic data image Sread composed of the binary pixel contrasts recorded in the storage medium 212 is reproduced.

The holographic data image Sread reproduced from the storage medium 212 passes through the Fourier lens 214 to the CCD 216, and the CCD 216 converts the reproduced data image Sread into an electrical data signal. The converted data is restored to the original data through an image signal processor, a decoder, and the like, which are not shown.

4 is a block diagram schematically illustrating a recording and reproducing apparatus of a holographic digital data storage system according to another embodiment of the present invention. Referring to FIG. 4, a recording and reproducing apparatus of a holographic digital data storage system according to another embodiment of the present invention includes a light source 300, an actuator 302 to which a pickup lens 302a is attached, and a Fourier lens. 304, 310, spatial light modulator (SLM) 306, storage medium 308, CCD 312, and the like. Although not shown in the figure, a shutter and an optical magnifying lens are added to the signal light path between the light source 300 and the Fourier lens 304. Here, the distance from the Fourier lens 304 to the storage medium 308 is set to the focal length F, and the distance from the storage medium 308 to the CCD 312 is set to an arbitrary distance L.

The light source 300 generates laser light for the reference light Sref path and the signal light Sobj path and transmits the laser light to the pickup lens 302a of the actuator 302 and to the Fourier lens 304.

The actuator 302 to which the pickup lens 302a is attached has a focal length of 2F to the Fourier lens 304. Since the position of the light incident on the Fourier lens 304 through the 2F focal length varies depending on the vertical position of the pickup lens 302a, the incident angle of the reference light Sref transmitted through the Fourier lens 304 in parallel light form. Is changed.

The Fourier lens 304 has a diameter size for transmitting both the light transmitted through the pickup lens 302a of the actuator 302 and the light of the light source 300. The Fourier lens 304 converts the light passing through the pickup lens 302a of the actuator 302 incident through the lens outside into a reference light Sref transmitted in parallel at a predetermined recording angle to the spatial light modulator 306. To pass. The Fourier lens 110 condenses the light of the light source 300 and transmits the light to the spatial light modulator 306.

The spatial light modulator (SLM) 306 transmits the reference light Sref incident from the Fourier lens 304 to transmit the reference light Sref through the reference light transmission region (a of FIG. 5) to the storage medium 308, and to the Fourier lens 304. The light emitted from the light source 300 is transmitted through the holographic data pattern (b of FIG. 5) configured in units of pages, and is modulated into a signal light Sobj and transmitted to the storage medium 308. Here, the reference light transmitting region (a of FIG. 5) of the spatial light modulator (SLM) 306 may have various shapes such as a circle and a rectangle.

The storage medium 308 is provided with a reference light (Sref) and a signal light (Sobj) modulated from the spatial light modulator (SLM) 308 incident through the spatial light modulator (SLM) 306 as parallel light of a predetermined recording angle. Record the interference fringes caused by the interference. At this time, in the recording apparatus according to another embodiment of the present invention, the light position where the light passing through the pickup lens 302a is incident on the Fourier lens 304 by the vertical movement of the pickup lens 302a of the actuator 302 is determined. By changing the angle of the reference light (Sref) is changed and transmitted to the storage medium 308 through the Fourier lens 304 as parallel light of the preset recording angle to hologram data at the same position of the storage medium 308 by an angle multiplexing method. You can record overlap.

The Fourier lens 310 located at the rear end of the storage medium 308 transmits the binary pixel data image (one page unit) (Sread) reproduced from the storage medium 308 to the CCD 312, and transmits the CCD (312). In 312, the reproduced data image Sread is photographed and the photographed signal is converted into an electrical data signal. The data converted by the CCD 312 is restored to the original data through an image signal processor, a decoder, and the like, which are not shown in the drawing.

The recording and reproducing apparatus of the holographic digital data storage system according to another embodiment of the present invention configured as described above operates as follows.

First, a portion of the laser light (for example, 532 nm wavelength laser light) generated in the light source 300 during recording is transmitted to the pickup lens 302a of the actuator 302 and the remaining light is transmitted to the Fourier lens 304.

The actuator 302 moves the pickup lens 302a to a vertical position according to a preset recording angle, and transmits the light of the light source 300 to the Fourier lens 304 through the pickup lens 302a.

The Fourier lens 304 converts the light passing through the pickup lens 302a of the actuator 302 into a reference light Sref transmitted in parallel at a preset recording angle, and transmits the light to the spatial light modulator 306, thereby transmitting the light source 300. Light is collected and transmitted to the spatial light modulator 306.

The spatial light modulator (SLM) 306 transmits the reference light Sref incident from the Fourier lens 304 at a preset recording angle to the storage medium 308 by transmitting it through the reference light transmitting region (a of FIG. 5), The light of the light source 300 incident from the Fourier lens 304 is transmitted through the holographic data pattern (b of FIG. 5) configured in units of pages, modulated into a signal light Sobj, and transmitted to the storage medium 308.

The signal light Sobj transmitted through the spatial light modulator (SLM) 306 and the reference light Sref incident through the spatial light modulator (SLM) 306 as parallel light at a predetermined angle are included in the storage medium 308. The interference pattern overlaps with each other in the recording material layer, causing interference, and the interference pattern is recorded according to the intensity of the interference pattern generated at this time. Accordingly, the recording device of the present embodiment also moves the pickup lens 302a of the actuator 302 vertically so that the reference light incident on the storage medium 308 through the Fourier lens 310 and the spatial light modulator (SLM) 306 ( The angle of Sref) can be adjusted to allow superimposition recording of hologram data on the storage medium 308 by an angle multiplexing method.

On the other hand, when the reproduction of the signal light (Sobj) to the storage medium 308 is blocked by the shutter added to the signal light path between the light source 300 to the Fourier lens 304, the laser light generated from the light source 300 is preset Passed through the pick-up lens 302a of the actuator 302 moved to the vertical position according to the angle, it is transmitted to the Fourier lens 304 and the spatial light modulator (SLM) 306.

When a reference light Sref having a preset recording angle is incident on the storage medium 308 through the spatial light modulator (SLM) 306, the holographic data image Sread recorded in the storage medium 308 is reproduced.

The holographic data image Sread reproduced in the storage medium 308 passes through the Fourier lens 310 to the CCD 312, and the CCD 302 converts the reproduced data image Sread into an electrical data signal. The converted data is restored to the original data through an image signal processor, a decoder, and the like, which are not shown.

As described above, the present invention records and reproduces holographic data by adjusting the angle of incidence of the reference light incident on the storage medium through an actuator with a pickup lens.

Therefore, the present invention can implement a recording and reproducing apparatus without using a conventional optical separator, a mirror and an actuator, thereby reducing the size of the entire system.

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 (16)

An apparatus for recording data by superimposing a reference light having a predetermined angle and a signal light having data information on a storage medium of a holographic digital data storage system, A light source for generating light, A spatial light modulator for transmitting a portion of the light through a reference light region and transmitting the remaining portion of the light through a holographic data pattern to modulate the signal into the signal light; An actuator for attaching a pickup lens for transmitting the light transmitted from the spatial light modulator and for moving the position of the pickup lens; A pair of lenses for transmitting the signal light transmitted from the spatial light modulator, A lens which transmits the light transmitted through the pickup lens in parallel to a predetermined angle and enters the storage medium as the reference light, and transmits the signal light transmitted through the pair of lenses to enter the storage medium. Recording device of the holographic digital data storage system comprising a. The method of claim 1, And the actuator changes the angle of the reference light incident on the storage medium through the lens by vertically shifting the position of the pickup lens. The method according to claim 1 or 2, The lens is a Fourier lens having a diameter for transmitting each light transmitted from the pickup lens and the pair of lenses, the holographic digital data storage system, characterized in that for transmitting the light transmitted from the pickup lens through the outside of the lens Recording device. The method according to claim 1 or 2, And the distance between the pick-up lens and the lens is 2F (F: focal length) and the distance between the last lens and the lens in the pair of lenses is 2F. An apparatus for recording data by superimposing a reference light having a predetermined angle and a signal light having data information on a storage medium of a holographic digital data storage system, A light source for generating light, An actuator for transmitting a part of the light of the light source, the actuator for moving the position of the pickup lens; A lens which transmits the light transmitted through the pickup lens as the reference light in parallel at a predetermined angle and transmits the remaining light portion of the light source; The reference light transmitted through the lens is transmitted through the reference light region to enter the storage medium, and the light transmitted through the lens is transmitted through the holographic data pattern to be modulated into the signal light to enter the storage medium. Light modulator Recording device of the holographic digital data storage system comprising a. The method of claim 5, And the actuator changes the angle of the reference light incident on the storage medium through the lens and the spatial light modulator by vertically shifting the position of the pickup lens. The method according to claim 5 or 6, The lens is a Fourier lens having a diameter for transmitting each of the light transmitted from the pickup lens and the light source, the recording of the holographic digital data storage system, characterized in that for transmitting the light transmitted from the pickup lens through the outside of the lens Device. The method according to claim 5 or 6, And the distance between the pickup lens and the lens is 2F (F: focal length) and the distance between the lens and the storage medium is 1F. An apparatus for reproducing data by injecting a reference light of a predetermined angle into a storage medium of a holographic digital data storage system, An actuator for attaching a pickup lens for transmitting light and for moving the position of the pickup lens; A lens that transmits the light transmitted through the pickup lens in parallel at a predetermined angle and enters the storage medium as the reference light. Playback device of the holographic digital data storage system comprising a. The method of claim 9, And the actuator changes the angle of the reference light incident on the storage medium through the lens by vertically shifting the position of the pickup lens. The method according to claim 9 or 10, And the lens is a Fourier lens and transmits light transmitted from the pickup lens through an outer portion of the lens. The method according to claim 9 or 10, And the distance between the pickup lens and the lens is 2F (F: focal length) and the distance between the lens and the storage medium is 1F. An apparatus for reproducing data by injecting a reference light of a predetermined angle into a storage medium of a holographic digital data storage system, An actuator for attaching a pickup lens for transmitting light and for moving the position of the pickup lens; A lens for transmitting the light transmitted through the pickup lens in parallel to a predetermined angle and transmitting the light to the reference light; A spatial light modulator for transmitting the reference light transmitted through the lens through the reference light region to enter the storage medium Playback device of the holographic digital data storage system comprising a. The method of claim 13, And the actuator changes the angle of the reference light incident on the storage medium through the lens and the spatial light modulator by vertically shifting the position of the pickup lens. The method according to claim 13 or 14, And the lens is a Fourier lens and transmits light transmitted from the pickup lens through an outer portion of the lens. The method according to claim 13 or 14, And the distance between the pickup lens and the lens is 2F (F: focal length) and the distance between the lens and the storage medium is 1F.

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