KR19990056446A - Volume holographic digital storage system - Google Patents

Abstract

The present invention relates to a volume holographic digital storage system for storing interference fringes generated by interfering light and modulated object light and reference light in units of pages of data, comprising: a polarization source 210 for generating the reference light having 45 ° polarization; When the 45 ° polarized reference light is irradiated, the storage medium is divided into an extraordinary beam and an ordinary beam, and outputs the recording light, and records an interference fringe generated by the interference between the reference light and the optically modulated object light. A filter 230 for generating object light by passing only one of the extractor beam and the auditory beam irradiated from the storage medium 220; A first reflection mirror 240 for reflecting the object light emitted from the filter 230 at a predetermined angle; A second reflective mirror 250 for irradiating the object medium radiated from the first reflective mirror 240 to the storage medium 220; A λ / 2 plate 260 for rotating the object light reflected by the second reflection mirror 250 by 90 °; And a spatial light modulator 270 that modulates the object light rotated by 90 ° in units of one page of light and shade binary data according to data input from the outside and irradiates the storage medium 220 to the storage medium 220. It is characterized by.

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 based on interference fringes generated by interfering object light from a target object and reference light. An improved 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 object light from a target object and a reference light from a target object, for example, a storage medium responding to the intensity of the interference fringe, for example, a crystal. By recording the intensity and direction of the object light by rotating the storage medium by a predetermined angle, etc., it is possible to display the three-dimensional image of the object, and to generate hundreds to thousands of holograms composed of pages of binary data. Can be stored in the same place.

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 separator 20, a reflection mirror 30, 40, a spatial light modulator 50, a storage medium 60, It consists of a Charge Coupled Device (CCD) 70.

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 object light, and then transmits the separated reference light and object light different from each other. Follow the path.

On the other hand, the reference light separated by the optical separator 20 is incident on the rotating mirror 30, and then reflected again and transmitted to the storage medium 60.

In addition, the object light is incident on the reflection mirror 40 and then reflected again and transmitted to the spatial light modulator 50. In this case, the spatial light modulator 50 is configured as a liquid crystal display (LCD), and thus, the object light provided to the spatial light modulator 50 is a unit of one page of binary data of contrast, which is formed by pixels according to input data. It is modulated and then transmitted to storage medium 60.

The storage medium 60 stores an interference fringe generated by interference between the reference light reflected by the reflective mirror 30 and the object light modulated in units of pages of data by the spatial light modulator 50, wherein the interference fringe Denotes data input to the spatial light modulator 50 described above.

The CCD 70 functions to convert the object light reproduced in the storage medium 60 into an electrical signal.

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 object light by the optical separator 20, and then the reference light is transmitted to the reflection mirror 30 and the object light is transmitted to the reflection mirror 40, respectively. The object light reflected by the reflection mirror 40 is incident on the spatial light modulator 50, and the object light incident on the spatial light modulator 50 is formed by the pixels according to data input to the spatial light modulator 50. Is modulated in units of one page of binary data.

That is, when the data input to the spatial light modulator 50 is image data provided in units of one frame of an image, for example, the object light incident on the spatial light modulator 50 is modulated by one frame unit. On the other hand, when the spatial light modulator 50 modulates the incident object light in units of pages of data, the storage medium 60 rotates by a predetermined angle step by step correspondingly.

Accordingly, the incident object light and the reference light cause interference in the storage medium 60. In this case, a light induction phenomenon of kinetic charge in the storage medium 60 occurs according to the intensity of the interference fringes generated. Through the recording medium 60, the interference fringes of the vector format having a predetermined direction and size corresponding to the rotation angle of the storage medium 60 is recorded, where the interference fringes correspond to the data.

On the other hand, if only the reference light is irradiated to the storage medium 60 to read the data recorded in the storage medium 60, the interference fringe is restored to the checkered pattern composed of the contrast of the original pixel by diffracting the reference light, and the storage medium The light modulated object light restored at 60 is reflected by the CCD 70 to restore the original data. Here, the reference light that has been applied to read the data recorded in the storage medium 60 should apply a reference light having substantially the same angle as the reference light that was applied when the data was recorded in the storage medium 60.

As such, conventional volume hologram digital storage systems are very complex in structure.

It is therefore an object of the present invention to provide an improved volume hologram digital storage system with a simpler structure.

In order to achieve the above object, the present invention provides a volume holographic digital storage system for storing an interference fringe generated by interfering a light modulated object light and a reference light in units of pages of data. Polarization source; A storage medium recording the interference light generated by the interference between the reference light and the optically modulated object light when the 45 ° polarized reference light is irradiated; A filter for generating object light by passing only one of the extractor beam and the auditory beam irradiated from the storage medium; A first reflection mirror reflecting object light emitted from the filter at a predetermined angle; A second reflection mirror that irradiates the storage medium with the object light radiated from the first reflection mirror; A λ / 2 plate for rotating the object light reflected by the second reflection mirror by 90 °; And a spatial light modulator for optically modulating the object light rotated by 90 ° in units of one page of light and dark binary data formed by pixels according to data input from the outside, and irradiating the storage medium to the storage medium.

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

2 is a detailed block diagram of a volume holographic digital storage system according to a preferred embodiment of the present invention.

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

210; Polarization source 220; Storage media

230; Filter 240,250; Reflective mirror

260; λ / 2 plate 270; Spatial light modulator

280; CCD

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

2 shows a detailed schematic diagram of an improved volume holographic digital storage system according to a preferred embodiment of the present invention.

In FIG. 2, an improved volume holographic digital storage system according to a preferred embodiment of the present invention comprises a polarization source 210, a storage medium 220, a filter 230, reflective mirrors 240, 250, [lambda] / 2 ([lambda]); Wavelength) plate 260, spatial light modulator 270, and CCD 280.

Here, the polarization source 210, the filter 230, and the reflection mirror 230 are arranged on the same horizontal line with respect to the storage medium 220, and the reflection mirror 250 and the λ / 2 plate 260. The spatial light modulator 270 and the CCD 280 are arranged on the same vertical line with respect to the storage medium 220, and the storage medium 220 described above is made of a crystal.

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

First, the polarization source 210 generates reference light of 45 ° polarization and irradiates the storage medium 220. When the storage medium 220 is irradiated with 45 ° polarized reference light, the storage medium 220 is divided into an extraordinary beam and an ordinary beam, and passes through the storage medium. To the filter 230.

The filter 230 generates object light by passing only one of the extractor beam and the auditory beam irradiated from the storage medium 220.

The reflection mirror 240 reflects the object light emitted from the filter 230 at a predetermined angle to irradiate the reflection mirror 250, and the reflection mirror 250 irradiates the λ / 2 plate 260 with it.

The λ / 2 plate 260 rotates the object light of the extraordinary beam or the ordinary beam by 90 ° to irradiate the spatial light modulator 270, and the spatial light modulator 270 emits the object light according to the input data. The storage medium 220 is irradiated by modulating it in units of one page of binary data of contrast.

Therefore, the interference pattern based on the reference light irradiated from the polarization source 210 and the light modulated object light irradiated from the spatial light modulator 270 is recorded in the storage medium 220. In addition, when the spatial light modulator 270 modulates the object light by one page unit of the binary data of the intensity of the pixels according to the input data, the storage medium 220 rotates at a predetermined angle corresponding thereto. The irradiation angle of the reference light irradiated to the storage medium 220 is converted one-to-one corresponding to the page unit of the object light.

In this case, for example, when the extraordinary beam passes through the filter 230, the object light of the extraordinary beam is irradiated to the λ / 2 plate 260 via the reflection mirror 240 and the reflection mirror 250, and then the audio Converted to object light in a remote beam.

When the extraordinary beam passes through the filter 230, the spatial light modulator 270 optically modulates the object light of the ordinary beam and irradiates the storage medium 220. On the other hand, the reference light of 45 ° polarized light emitted from the polarization source 210 to the storage medium 220 is divided into an extra ordinary beam and an ordinary beam in the storage medium 220, and the ordinary beam is optically modulated in the storage medium 220. Will cause interference with the object light.

At this time, since the light modulated object light is an ordinary beam, the reference light causing interference with the light modulated object light becomes a reference light of the ordinary beam, and the reference light of the extra ordinary beam passes through the storage medium 220 without interference. 230).

That is, when the filter 230 passes the extraordinary beam, the storage medium 220 causes the object light of the photomodulated beam and the reference light of the ordinary beam to interfere with each other. Although distortion is generated by the interference, the reference light of the extra ordinary beam without interference is provided to the filter 230 without distortion.

On the other hand, when the filter 230 is irradiated with the reference light of the distortion and the extraordinary beam without distortion, when the reference light of the distorted ordinary beam is irradiated, the filter 230 passes only the extra-ordinary beam without distortion as described above and uses the object light of the ordinary beam In this case, a clearer interference fringe is recorded in the storage medium 220.

On the contrary, for example, if the filter 230 passes an ordinary beam, the object light of the ordinary beam is irradiated to the λ / 2 plate 260 via the reflection mirror 240 and the reflection mirror 250 and then the extra audio Converted to object light in a remote beam.

Therefore, when the filter 230 passes the ordinary beam, the spatial light modulator 270 light modulates the object light of the extra ordinary beam and irradiates the storage medium 220. Meanwhile, the 45 ° polarized reference light radiated from the polarization source 210 to the storage medium 220 is divided into an extra ordinary beam and an ordinary beam in the storage medium 220, and the extra ordinary light modulated in the storage medium 220. Interfere with the object light of the beam.

At this time, since the light modulated object light is an extra-ordinary beam, the reference light causing interference with the light-modulated object light becomes a reference light of the extra-ordinary beam, and the reference light of the ordinary beam passes through the storage medium 220 without interference. 230 is irradiated.

That is, when the filter 230 passes the auditory beam, the storage medium 220 causes the object light of the optically modulated extra-ordinary beam and the reference light of the extra-ordinary beam to interfere with each other, thereby causing the interference of the extra-ordinary beam. The reference light is distorted by interference, but the reference light of the ordinary beam without interference is provided to the filter 230 without distortion.

On the other hand, the filter 230, when the reference light of the extraordinary beam with distortion and the reference light of the ordinary beam without distortion is irradiated, as described above, passes only the ordinary beam without distortion, by using the object of the extraordinary beam Since light is generated, clearer interference fringes are recorded in the storage medium 220.

The interference fringe recorded in this way is reproduced when the reference light of the extraordinary beam or the reference light of the ordinary beam is irradiated with the same irradiation angle as at the time of recording and is converted into an electrical signal by the CCD 280.

As described above, the present invention has the effect of recording a clearer interference fringe with a simpler structure.

Claims (1)

In a volume holographic digital storage system for storing an interference fringe generated by interfering a light modulated object light and a reference light by page of data: A polarization source 210 for generating the reference light of 45 ° polarization; When the 45 ° polarized reference light is irradiated, the storage medium is divided into an extraordinary beam and an ordinary beam, and outputs the recording light, and records an interference fringe generated by the interference between the reference light and the optically modulated object light. A filter 230 for generating object light by passing only one of the extractor beam and the auditory beam irradiated from the storage medium 220; A first reflection mirror 240 for reflecting the object light emitted from the filter 230 at a predetermined angle; A second reflective mirror 250 for irradiating the object medium radiated from the first reflective mirror 240 to the storage medium 220; A λ / 2 plate 260 for rotating the object light reflected by the second reflection mirror 250 by 90 °; And a spatial light modulator 270 that modulates the object light rotated by 90 ° in units of one page of light and shade binary data according to data input from the outside, and irradiates the storage medium 220 to the storage medium 220. Volume holographic digital storage system.