KR100275278B1 - Volume holographic digital data storage system - Google Patents

Abstract

The present invention relates to a volume holographic digital storage system, comprising: a light source (210) for generating the predetermined laser beam; An optical separator for separating the laser beam into a reference light and a signal light and then transmitting the reference light on the first optical path, and transmitting the signal light on the second optical path; A first reflection mirror 230 for reflecting the reference light on the first optical path and transmitting the reference light on a third optical path; A second reflecting mirror 240 reflecting the signal light on the second optical path and transmitting the reflected light on the fourth optical path; A spatial light modulator (250) for optically modulating the signal light on the fourth path in units of one page of binary data; Both sides are spherical, the top and back surfaces are planar, and the cross section is elliptical. When the spatial light modulator 250 optically modulates the signal light by one page of binary data, it rotates at a predetermined angle corresponding thereto. And angular multiplexing the interference fringes based on the reference light incident on the upper surface and the light modulated signal light converged from the one spherical surface, and reproducing the light modulated signal light when the reference light for reproduction is irradiated. The fourth optical path through which the optically modulated signal light is transmitted, forms a total reflection critical angle with the rear surface, and the emitted optically modulated signal light converges on the other spherical surface. ; And a CCD 270 for converting the optically modulated signal light reproduced in the storage medium 260 into an electrical signal.

Description

Volume holographic digital storage system

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a volume holographic digital data storage system for storing hologram data in units of pages based on interference fringes generated by interfering signal light from a target object and reference light. The structure relates to a volume holographic digital storage system.

Recently, the field of technology using volume holographic digital data storage has been actively researched due to the remarkable development of components such as semiconductor laser, charge coupled device (CCD), liquid crystal display (LCD), and fingerprint storage. In addition to being used as a fingerprint recognition system to play and play, there is a trend of expanding to various fields that can apply the advantages of large storage capacity and ultra-fast data transfer speed.

Such a volume holographic digital storage system records an interference fringe generated by interfering a signal light from a target object and a reference light, such as a crystal, in a storage medium responsive to the amplitude of the interference fringe. By recording the intensity and direction of the signal light by changing the angle of the reference light, etc., it is possible to display the three-dimensional image of the object, and to place hundreds to thousands of holograms composed of pages of binary data in the same place. You can save it.

Figure 1 shows the overall configuration of such a volume holographic digital storage system.

As shown in FIG. 1, a volume holographic digital storage system includes a light source 10, a light splitter 20, reflective mirrors 30 and 40, a liquid crystal display (LCD) 50, a vertical AOD ( Acousto Optical Device (60), horizontal AOD 70, storage medium 80, CCD 90, and Fourier lenses (fourier, 100, 110).

The light source 10 generates laser light required for holography, and the optical separator 20 separates the laser light input from the light source 10 into reference light and signal light, and then separates the transmission path from which the separated reference light and signal light are different. Take it through.

The vertical AOD 60 deflects the reference light in the vertical direction, thereby providing the spatially multiplexed reference light to the reflective mirror 30. The reflection mirror 30 is disposed to be inclined at 45 ° to reflect the incident reference light to change the transmission path of the reference light, and the horizontal AOD 70 deflects the reference light in the horizontal direction to store the angle multiplexed reference light. To provide.

On the other hand, the reflection mirror 40 is arranged to be inclined 45 ° to convert the transmission path of the signal light, the LCD 50 modulates the signal light by one page unit of the binary data of the contrast of the pixels made in accordance with the input data to the Fourier Transmit to the lens 100.

The Fourier lens 100 converges the spatial light modulated signal light to remove noise and irradiates the storage medium 80, and the Fourier lens 110 converges the reproduction light emitted from the storage medium 90 to the original light. Restore the function.

The storage medium 80 stores an interference fringe generated by the interference between the reference light irradiated from the horizontal AOD 70 and the light modulated signal light converged by the Fourier lens 100, wherein the interference fringe is the LCD (see above). This corresponds to the data entered in 50).

The operation of the volume holographic digital storage system configured as described above is as follows.

First, the laser light generated by the light source 10 is separated into the reference light and the signal light by the optical separator 20, and then the reference light is transmitted to the vertical AOD 60 and the signal light to the reflection mirror 40, respectively. The reflection mirror 40 reflects the incident signal light toward the LCD 50 side, and the signal light incident on the LCD 50 is in units of one page of binary data of contrast, which pixels form according to data input to the LCD 50. Is modulated.

That is, when the data input to the LCD 50 is image data provided in one frame unit of an image, for example, the signal light incident on the LCD 50 is modulated in one frame unit.

The signal light modulated in units of frames is provided to the Fourier lens 100, and the Fourier lens 100 converges it to remove noise and irradiates the storage medium 80.

Meanwhile, the reference light separated by the optical separator 20 is provided to the vertical AOD 60, and the vertical AOD 60 deflects the reference light in the vertical direction, but the signal light incident on the LCD 50 is in the unit of the page of data. When modulated, the vertical deflection angle of the reference light is adjusted to step by step correspondingly.

The reference light deflected at a predetermined vertical angle is reflected by the reflection mirror 30 and then irradiated to the horizontal AOD 70, and the horizontal AOD 70 deflects it in the horizontal direction to irradiate the storage medium 80.

Therefore, the reference light irradiated to the storage medium 80 is light deflected at predetermined vertical and horizontal angles, wherein the reference light irradiated to the storage medium 80 is perpendicular to the storage medium 80 by the vertical AOD 60. Scanned in the horizontal direction of the storage medium 80 by the horizontal AOD 70.

The optically modulated signal light is input to the storage medium 80 in units of pages, and the vertical / horizontally deflected reference light is incident as described above. Thus, the incident signal light and the reference light cause interference within the storage medium 80. do.

At this time, the light induced phenomenon of the kinetic charge in the storage medium 80 occurs according to the intensity of the generated interference fringes, and through this process, the interference fringes are recorded in the storage medium 80.

On the other hand, in order to read the data recorded on the storage medium 80, only the reference light is irradiated to the storage medium 80, and the interference fringe is diffracted into the checkered pattern consisting of the contrast of the original pixel by diffracting the reference light. The reproduced light is divergent because it was converged and recorded during recording. Accordingly, the Fourier lens 110 restores the emitted light to the original data in the light of a CCD (Charge Coupled Device) 70 or the like. At this time, the reference light that has been applied to read data recorded in the storage medium 80 should apply a reference light having substantially the same intensity and angle as the reference light applied when the data is recorded in the storage medium 80.

As described above, the conventional volume holographic digital storage system has a Fourier lens for noise removal, has a relatively complicated structure, and has a problem of being inadequate in terms of economy due to the use of expensive AOD.

The present invention has been made to solve the above problems, and an object thereof is to provide a volume holographic digital storage system capable of storing and reproducing hologram data with a cheaper and simpler structure.

In order to achieve the above object, the present invention provides a volume holographic digital storage system comprising: a light source for generating the predetermined laser beam; An optical separator for separating the laser beam into a reference light and a signal light and transmitting the reference light on a first optical path, and transmitting the signal light on a second optical path; A first reflection mirror that reflects the reference light on the first optical path and transmits the reference light on a third optical path; A second reflection mirror which reflects the signal light on the second optical path and transmits it on the fourth optical path; A spatial light modulator for optically modulating the signal light on the fourth path in units of one page of binary data; Both sides are spherical, the top and back surfaces are planar, and the cross section is elliptical, and when the spatial light modulator optically modulates the signal light by one page of binary data, the top surface is rotated at a predetermined angle corresponding thereto. And angular multiplexing the interference fringes based on the reference light incident perpendicularly to and the light modulated signal light converged from the one spherical surface, and reproducing the light modulated signal light when the reference light for reproduction is irradiated. A fourth storage path, the fourth optical path of which the optically modulated signal light is transmitted, forms a total reflection critical angle with the rear surface, and the optically modulated signal light that converges from the other spherical surface; And a CCD for converting the optically modulated signal light reproduced in the storage medium into an electrical signal.

1 is a block diagram of a volume holographic digital storage system of the prior art,

2 is a detailed schematic diagram of an improved volume holographic digital storage system in accordance with a preferred embodiment of the present invention.

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

210: light source 220: beam splitter

230, 240: reflection mirror 250: spatial light modulator

260: storage medium 270: CCD

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

2 shows a volume holographic digital storage system according to a preferred embodiment of the present invention.

In FIG. 2, a volume holographic digital storage system according to a preferred embodiment of the present invention includes a light source 210, an optical splitter 220, reflective mirrors 230 and 240, a spatial light modulator 250, and a storage medium 260. ), The CCD 270.

Here, the storage medium 260 is made of a LiNbO ₃ crystal having a refractive index of 2.4 and a total reflection critical angle of 25 °, having a spherical surface on both sides, a top surface and a back surface, and an oval cross section, as shown in FIG. It is inclined at an angle.

The operation of the volume holographic digital storage system according to the preferred embodiment of the present invention configured as described above is as follows.

First, the laser light generated by the light source 210 is separated into a reference light and a signal light by the optical separator 220. The optical separator 220 transmits the separated reference light on the first optical path, and transmits the signal light on the second optical path perpendicular to the first optical path.

The reflective mirror 230 reflects the reference light incident through the first optical path at a predetermined angle θ, preferably 95 ° to 115 °, so that the upper surface of the storage medium 260 is irradiated through the third optical path. .

On the other hand, the signal light transmitted by the optical splitter 220 on the second optical path is reflected by the reflection mirror 240 by 90 degrees, and is transmitted in the fourth optical path that is parallel to the first optical path. The spatial light modulator 250 modulates the signal light on the fourth path by one page unit of the binary data of light and shade formed by the pixels according to the data, and irradiates the spherical surface of the storage medium 260.

In this case, the storage medium 260 is inclined at a predetermined angle on the fourth optical path, preferably 5 ° to 25 °, so that the reference light irradiated from the reflection mirror 230 is perpendicular to the upper surface of the storage medium 260. Incident. In addition, the optically modulated signal light irradiated from the spatial light modulator 250 is incident on one side surface of the storage medium 260 and then collected by refraction and converged on the back surface of the storage medium 260, and then totally reflected on the back surface, thereby causing storage medium Transmitted through the other side of 260.

Accordingly, the reference light incident through the upper surface of the storage medium 260 and the light modulated signal light converged from the spherical surface cause interference in the storage medium 260, and thus an interference fringe is recorded.

Meanwhile, when the spatial light modulator 250 optically modulates the signal light in units of one page of binary data, the storage medium 260 rotates little by little at a predetermined angle corresponding thereto, and rotates left and right parallel to the rear surface. As the storage medium 260 rotates by a predetermined angle, the incident position of the signal light is slightly changed, and the interference fringe is angularly multiplexed and recorded in units of pages of data in the storage medium 260.

In order to reproduce the interference fringe corresponding to the hologram data recorded by the angular multiplexing on the storage medium 260 based on the above-described process, the storage medium 260 is rotated by a predetermined angle and the same as when recording on the storage medium 260. When the reference light of intensity is irradiated, an interference fringe stored in the storage medium 260 diffracts the reference light, thereby reproducing the light modulated signal light. At this time, the reproduced light-modulated signal light is totally reflected from the rear surface of the storage medium 260 and diverged to the other side surface of the storage medium 260, and then converged at the other side surface of the storage medium 260 and transmitted to the CCD 270. Thus, the CCD 270 picks up the light modulated signal light and converts it into an electrical signal.

As described above, the present invention enables the storage medium itself to function as a Fourier lens, realizes angular multiplexing by rotating the storage medium, and records and reproduces data using total reflection, thereby making it cheaper and simpler. There is an effect that can be implemented.

Claims (2)

For volume holographic digital storage systems: A light source 210 generating the predetermined laser beam; An optical separator for separating the laser beam into a reference light and a signal light and then transmitting the reference light on the first optical path, and transmitting the signal light on the second optical path; A first reflection mirror 230 for reflecting the reference light on the first optical path and transmitting the reference light on a third optical path; A second reflecting mirror 240 reflecting the signal light on the second optical path and transmitting the reflected light on the fourth optical path; A spatial light modulator (250) for optically modulating the signal light on the fourth path in units of one page of binary data; Both sides are spherical, the top and back surfaces are planar, and the cross section is elliptical. When the spatial light modulator 250 optically modulates the signal light by one page of binary data, it rotates at a predetermined angle corresponding thereto. And angular multiplexing the interference fringes based on the reference light incident on the upper surface and the light modulated signal light converged from the one spherical surface, and reproducing the light modulated signal light when the reference light for reproduction is irradiated. The fourth optical path through which the optically modulated signal light is transmitted, forms a total reflection critical angle with the rear surface, and the emitted optically modulated signal light converges on the other spherical surface. ; And a CCD (270) for converting the optically modulated signal light reproduced in the storage medium (260) into an electrical signal. The volume holographic digital storage system of claim 1, wherein the storage medium (340) has a total reflection critical angle of 25 degrees.